Alternative Futures



for the
Department of Energy
National Laboratories




Prepared by the
Secretary Of Energy Advisory Board



Task Force on Alternative Futures for the
Department of Energy National Laboratories



February 1995



 






Task Force on Alternative Futures for the DOE National 
Laboratories



Robert Galvin  (Chairman) Chairman of 
the Executive Committee
Motorola Inc.

Braden Allenby
Research Vice President, Technology 
and Environment
AT&T

Bob Boylan
Successful Presentations
A Division of Boylan Enterprises, Inc.

Linda Capuano 	
Vice President,
Operations and Business Development
Conductus, Inc.

Ruth Davis
President and Chief Executive Officer
Pymatuning Group

Marye Anne Fox
Vice President for Research
Waggoner Regents Chair
	Department of Chemistry
University of Texas

Benjamin Huberman	
President
Huberman Consulting Group

Shirley Jackson 		 
Professor
Department of Physics and Astronomy
Rutgers University

Lynn Jelinski
Director,  Center for Advanced 
Technology (Biotechnology)
Cornell University

Henry Kendall
Professor of Physics, Massachusetts 
Institute of Technology
Chairman, Union of Concerned 
Scientists



Daniel Kerlinsky
President, New Mexico Physicians for 
Social Responsibility
Children's Psychiatrist, University of 
New Mexico

Richard Lester
Director, MIT Industrial Performance 
Center
Professor of Nuclear Engineering
Massachusetts Institute of Technology

Roger Little
President and Chief Executive Officer
Spire Corporation

Edith Martin
Executive Vice President and Chief 
Technology Officer
Sallie Mae

James P. McCarthy
General, USAF (Ret)
Olin Professor of National Security
US Air Force Academy

Mark Murphy
President
Strata Production Company

Richard Nelson
George Blumenthal Professor of 
International and Public 
Affairs, Business, and Law
Columbia University

Edward Roberts
David Sarnoff Professor of Management
Faculty Chair,  Management of 
Technology Program
Massachusetts Institute of Technology

Benjamin M. Rosen
Chairman of the Board, Compaq 
Computer
Partner, Sevin Rosen Management




Harvey M. Sapolsky
Director, MIT Defense & Arms Control 
Studies Program
Professor of Public Policy
Massachusetts Institute of Technology

William Spencer
President and Chief Executive Officer
SEMATECH

Victoria Tschinkel 	
Senior Consultant
Landers & Parsons

Herbert York
Director Emeritus of the Institute for 
Global Conflict and Cooperation
University of California

Task Force Staff

Peter F. Didisheim
Executive Director
Secretary of Energy Advisory Board
U.S. Department of Energy

Michele M. Donovan
Task Force Director
U.S. Department of Energy


I. OVERVIEW	
A. Introduction	
B. Missions of the National Laboratories	
C. Laboratory Governance	
D. Configuration of the Laboratories	
II. THE NATIONAL SECURITY ROLE	
A. Introduction and Background	
B. Main Findings and Recommendations	
C. Summary of Recommendations	
III. THE ENERGY, ENVIRONMENT, AND RELATED SCIENCES AND 
ENGINEERING 
ROLE	
A. Main Findings	
B. Recommendations	
IV. THE ENVIRONMENTAL CLEANUP ROLE	
A. Introduction	
B. Background	
C. Main Findings	
D. Disconnects	
E. The Future	
F. Concluding Remarks	
G. Recommendations	
V. THE SCIENCE-ENGINEERING ROLE	
A. Main Findings	
B. Recommendations	
VI. THE ECONOMIC ROLE	
A. Main Findings	
B. Recommendations	
VII. THE GOVERNANCE AND ORGANIZATION ISSUE	
A. Introduction	
B. The Need to De-Federalize	
C. Other Subjects	
D. Recommendation	
VIII. SUMMARY OF RECOMMENDATIONS	
A. National Security	
B. Energy, Environment, and Related Sciences and Engineering 
Role	
C. Cleanup of Radioactive and Chemical Wastes	
D. Science-Engineering	
E. Economic	
F. Governance	

Appendices
A. EXCESSIVE OVERSIGHT AND MICROMANAGING
B. IF GOCO SYSTEM IS OBLIGED
C. TERMS OF REFERENCE



I.Overview





A.	Introduction



This Task Force was asked to propose alternate futures for the Department of 
Energy laboratories noted in Figure 1(see inside front cover).  The Task Force 
Charter is provided in Appendix C.  Our intensive ten months’ study 
revealed multiple missions and sub-missions --  traditional missions and new 
missions --  programs and projects --  each with factors of merit.  Each 
iteration of our study would nevertheless still confound even the members of 
the Department and laboratory community, as evidenced by the oft-
quoted statement:   the laboratories, and indeed the Department, require a 
clearer, more focused statement of mission! .  Our sorting  of these matters 
has led us to a synthesis which when first revealed may appear too simple, 
too limiting or even too much of a play on  words.  But we respectfully 
suggest that this synthesis identifies an 
Our working definition of Energy is:  Energy is power 
capable of doing work.  The Physical, Chemical, and 
Biological Sciences which are used to derive fuels from 
natural resources are in turn enabled by Energy.  
Conventional energy sources include wood, water, oil, 
gas, coal, and nuclear fuels.  The growing U.S. and 
world population requires all these, as well as new 
source such as solar energy, biomass, and wind energy.  
All must be made clean, safe, less expensive, and in the 
aggregate, abundant.  Energy may be sourced 
centrally, locally, or portably.  It must be generated, 
transformed, distributed, and properly utilized from all 
these sources.  Future sources may include, for 
example, hydrogen, which is abundant in water, gas, 
and biomass; albeit a  challenge to  extract  and store.  
DOE laboratory scientists have decades of experience 
with hydrogen and other basic sources.  Their multidisci-
plinary competencies hold the promise of solving many 
such challenges.
essence --   the essence of what the Department, and particularly the laboratories, should 
and do stand for: the energy agenda.

Virtually everything the laboratories do  is  energy.  The original laboratories’ first assignment 
was a nuclear energy bomb --  developing the fuel, storing and containing the energy, 
and releasing the energy.  More laboratories were formed and/or augmented in response 
to other energy needs which occasionally were identified as crises.  Newer laboratories 
have credentials (among other credentials) for conservation and renewable energy.  Most 
of the laboratories are concerned and resourced to deal with the various effluents of 
energy and its applications vis-a-vis the environment.  The aggregate of science and 
technology competencies of the laboratories has served, and continues to serve, as one 
essential resource for the study of energy.
At many given points in time energy is the paramount issue in our lives.   A blackout in a 
nearby neighborhood or industrial plant is always headline news.  Long lines of vehicles 
responding to (infrequent)  fuel shortages capture everyone’s self-interest.  Although we 
are privileged to more often take energy availability for granted in the United States, we still 
press for longer battery life for our cellular phones and worry that some day we will run out 
of petroleum.  Energy is so central to the vitality of our dynamic country that it has to be a 
priority concern as an ongoing national strategic issue.  It may be legitimately referred to 
as an issue of importance to our general long-term national security.

As we were in the latter stages of writing this report, occasional speculation surfaced 
concerning the continuing role of the Department of Energy, and suggesting in part that 
energy is not all that important.  Such major agency structure issues are beyond our 
purview, but we do feel justified in asserting that the energy agenda which we will profile in 
this report does require central, federal, senior cognizance and appropriate government 
sponsorship in the interest of the short-term and long-term overall quality of life in America 
and the world.  We will shortly make the point that the laboratories are essential (with 
appropriate changes, of course) in these regards.  The laboratories we studied require a 
strong federal financial support and linkage or sponsorship, at least for a goodly number of 
years, for reasons that will be evident throughout this report.  The Department can serve 
this  role, appropriately redefined, well.

Returning to the subject of mission, we find ourselves comfortable with a mission whose 
meaning is bound up in serving energy opportunities.  We introduce the thought with 
words that are not capitalized because we do not want to presume to capture as graphic 
art an all-encompassing meaning in a few short words.  Nor do we believe that the 
Department or laboratories have been adequately served by articulating virtual slogans in 
some of its noble efforts at projecting its purposes.  Yet, even if one flashes the message  
Serving the Energy Opportunities  on the proverbial screen, in its own quiet way it conveys 
what almost every other existing mission or program or project intended.





Let us narrow in on the word energy  and its meaning.  The word serves as the remarkable 
root word for defining mission(s) within a progressive parameter.  At one and the same 
time, it gives focus and gives a wide-ranging field of relevant explorations.

Elsewhere in this report one will find our recommendation of need for focus --  a parameter 
of sorts to the roles of the laboratories.  Yet it is not inconsistent that simultaneously we 
recommend the laboratories must be free to renew and press the frontiers in all relevant 
affordable ways in behalf of their energy agenda, broadly defined.

The rest of the world has an energy agenda of sorts as well.  This agenda is to --  obtain for 
their people access to energy supplies comparable in all respects to --  those we now 
enjoy.  This global energy agenda represents a huge opportunity for the U. S. energy 
industries.  It also represents a competitive threat to those industries if they have not 
prepared and committed first to serve the right  product.   Finally, it represents  a threat to 
our country and other countries if some nations employ technologies for energy 
production and usage which increase global pollution levels.  Our purveyors to those  
expanding producing and using societies must be prepared to offer better.  While serving 
the needs of our country with the leading edge of technology, we can best serve the 
needs of other countries, both environmentally and commercially, when we support them 
with technologies derived or derivable by the laboratories.  All these self-evident 
contributions from the laboratories are in addition to the national security, defense and  
weapons stewardship role that gave birth to the first laboratories.  This latter role will be a 
continuing irrevocable obligation for a minimum of two score more years.

The laboratories’ research role is a part of an essential, fundamental cornerstone for 
continuing leadership by the United States.  We know that the studies and discoveries of 
science unravel the elements of nature and shower benefits on mankind.  We know by 
intelligent estimates that there is much more to be learned and shared.  We know that 
these scientific revelations will unfold from many sources:  a brilliant insight by an individual, 
a research team at a university, a corporate or government laboratory --   by accident, or 
on purpose.  We know progress is hastened where diversity of personnel and institutions is 
encouraged.

We note that many of the least exploited investigative paths involve the need for 
extraordinarily sophisticated multidisciplinary teams using sophisticated instruments and 
tools.  It is that role for which the national laboratories are uniquely qualified.  It is the case 
for --   the justification of  --   the existence of the DOE laboratories.

Yet most citizens do not know enough about the laboratories.  We do not know the 
thousands of insights, new directions, new phenomena, new principles, materials and 
processes that blanket these laboratories’ science spectrum, all relevant to an energy 
agenda. Examples include the world’s most intense X-ray sources; biomedical isotopes; 
chlorofluorocarbon substitutes; computer models of combustion for cleaner energy; laser 
isotope separation; lasers for pollution monitoring; neutron sources to probe materials and 
biological systems; the unraveling of the puzzles of the human genetic code; the 
harnessing of the wind, sun and earth for renewable energy; superconductivity; global 
ocean and atmospheric studies; detection and tracking of nuclear materials; fossil, fission, 
fusion energy; novel semiconductor materials and devices; laser destruction of blood clots; 
bioremediation of radioactive and hazardous waste; accelerator technology for medical 
applications; and remediation of radioactive storage tanks.  These are but a few 
examples.

We are inclined to typecast these institutions simplistically by a few prominent contributions 
such as yesterday’s bomb or the discovery of an element on the periodic table (both 
grand achievements), but overlook the multitude of other continuing achievements.  We 
must reach out to know enough of this vast spectrum of accomplishments to justify our 
deserved support of these institutions that have contributed, are contributing,  and will in 
the future contribute vital knowledge while continuing to revitalize themselves --  just as 
science always renews itself.  We must be in quest of that which we do not know in the 
field of science in every relevant way.  Each revelation will enrich us manyfold.  The 
laboratories we review here are essential to the fulfillment of our need to know.

Under the overarching energy agenda --  the labs serving the energy opportunities --  we 
will comment on their national security role, the all important energy role, all related 
environmental roles, the  science and engineering underpinning for all the above, a 
focused economic role, and conclude with governance / organization change 
recommendations.




B.	Missions of the National Laboratories

The Task Force believes that a change of governance of the national laboratories 
is necessary regardless of the missions of these multi-program institutions.  However, 
we also have strong views regarding the appropriate mission activities for the 
laboratories.  One general observation of the Task Force is that the national 
laboratories, and the Department, appear to believe that they have the potential 
to serve an extraordinarily broad role in scientific investigation and technical 
research for the nation.  The Task Force does not support this view.  Rather, we see 
the laboratories as having clear areas of expertise, yet limited to their traditional 
mission areas of national security, energy, and environmental science and 
technology, as well as in the fields of fundamental science which underpin these 
missions and in basic science associated with high energy,  nuclear, and 
condensed matter physics.

While the Task Force supports innovative application of the national laboratories’ 
core technical competencies (for example, high performance computation, 
advanced materials, energy technologies, and systems engineering) to new 
problem areas, these activities should be carefully managed, are not likely to 
evolve into  new missions  per se, and should not be a license to expand into areas 
of science and technology which already are being addressed effectively or 
more appropriately by other Research and Development (R&D) performers in 
government, academia and the private sector.

The Task Force does believe that the national laboratories serve a distinctive role in 
conducting long-term, often high-risk R&D, frequently through the utilization of 
capital-intensive facilities which are beyond the financial reach of industry and 
academia, and generally through the application of multidisciplinary teams of 
scientists and engineers.  We believe that an appropriate division of labor among 
the national laboratories, industrial research institutions, and research universities 
can be established but does not sufficiently now exist.
	
The Task Force concluded that the work of these laboratories contributes in an 
important, though generalized fashion to the security interests of the nation, when 
security is defined broadly to include factors such as:



	-Developing technologies which enhance the ability of the nation to 
deter and defend against military threats, to reduce the nuclear danger, 
and enhance confidence in our own nuclear weapons in the absence of 
explosive testing;
		
	-Enhancing the prospect for sound patterns of energy use through the 
development of diverse, efficient, and sustainable energy technologies;
		
	-Reducing environmental threats posed by the waste legacy of the 
nuclear weapons program and by the careful utilization of energy  and 
materials throughout the economy;  and,
		
	-Expanding the base of scientific information -- which is one of the 
nation’s greatest long-term strategic assets -- through pioneering work in a 
number of areas of fundamental science mostly related to the energy 
agenda.



One general observation about the missions of the laboratories is that the Task 
Force found it ironic that these institutions seem to be searching so hard for  new 
missions  when there remains a compelling agenda of important work to be 
performed in their traditional mission areas.   The Task Force believes:



	-The existing budget of the national laboratory system exceeds that 
required to perform its agenda in the areas of national security, energy, 
environment, and fundamental science;
		
	-It is unrealistic for these institutions to attempt to retain their current size 
by laying claim to  new missions;  and,
		
	-The urgent requirement for these laboratories is to provide more 
disciplined focus on the new research needs within the traditional set of 
mission areas, as described below.



Later we identify savings through reorganization which can be variously used to 
reduce budget, redeploy resources, and increase research in appropriate areas.


	1.	National Security

The primary national security mission of the DOE laboratories is to provide for a 
safe, secure and reliable nuclear stockpile in the absence of  explosive testing of 
nuclear weapons.  Continued scientific, engineering, and managerial excellence 
will be required at the laboratories to meet the complex and demanding 
stewardship role.  A vital extension of this mission involves work in non-proliferation, 
counter-proliferation, arms control verification, and intelligence support.  Another 
critical and daunting national security task for which the weapons laboratories 
have special expertise involves the safe tracking and disposition of fissionable 
materials.


	2.	Energy

The primary mission for the laboratories in relation to energy technologies is to 
pursue a research and technology development agenda which enhances the 
long-term prospects for adequate energy supplies and efficient end use 
technologies which minimize adverse environmental impacts.  The primary role for 
the laboratories should be in areas where long-term research holds the prospect 
for significant payoffs, and where a clear public purpose is being served through 
Federal support.  To the maximum extent possible, energy R&D at the laboratories 
should be coordinated with the private sector and be guided by technology road 
maps.


	3.	Environmental Science and Technology

The Department faces a monumental task in dealing with the radioactive and 
hazardous wastes at its former nuclear weapons production sites and national 
laboratories.  This task cannot be  addressed in an affordable fashion using today’s 
technologies.  The national laboratories have expertise and untapped potential 
which could accelerate the scientific and technological base which is urgently 
needed for the cleanup mission.

The laboratories also have significant contributions to make in research and 
development related to more efficient utilization of energy and materials, such as 
pollution prevention and waste minimization techniques, and also in areas 
associated with the environmental impacts of energy use, as in global climate 
modeling.  The Task Force believes that the laboratories have areas of 
demonstrated expertise that could provide the basis for an expanded mission in 
environmental research and technology development, but such expansion should 
occur only in areas where the laboratories have a comparative advantage to 
other R&D performers in academia, industry, or other government agencies.


	4.	Fundamental Science

The national laboratories have a major mission to serve in contributing to the 
scientific foundation which underpins the Department’s other mission areas:  
national security, energy, and the environment.  The laboratories also have 
important responsibilities in certain discrete areas of science for which mission 
applications are not immediately apparent - such as in high energy, nuclear, and 
condensed matter physics - but where contributions to the nation’s scientific 
enterprise have been significant.

Such contributions often have derived from large-scale scientific user facilities that 
have been built and operated at the national laboratories (as well as at the 
Department’s program-dedicated laboratories).  Such facilities have enabled 
government, academic, and industrial researchers to explore scientific frontiers 
that have not been accessible in other ways.  Long-term, fundamental research of 
this form has been part of the national endeavor to create a better future through 
investments which could have a transforming, yet unknowable impact on society.  
The Department should sustain and strengthen its support of fundamental science.


	5.	Industrial Technologies

Development of technologies for which private sector companies are the major 
beneficiary is not an appropriate mission for the national laboratories.  Rather, the 
economic impact of R&D performed for such general benefit by the national 
laboratories should be viewed as a derivative, or outcome, of the other core 
missions.  Collaborations between the national laboratories and the private sector 
serve the important function of providing dual benefits to the partners, but such 
collaborations generally should be closely aligned with core mission areas of the 
Department.  To the extent appropriate, such collaborations should be cost-
shared and tied to technology road maps developed by and with industrial 
sectors.


C.	Laboratory Governance

Our study revealed a counterproductive federal system of operation (Department, 
Contractor, Laboratory and substantially driven by Congressional policies).  A far-
less-federal system must be authorized by the Congress, adopted by the 
Department and  implemented at the laboratories, possibly involving contractors.  
Certain far-less-federal systems promise large productivity gains with attendant 
major economies along with refreshed motivation by empowerment of the 
laboratory’s greatest assets -- its devoted professionals.  We urge embracing such 
a new concept promptly, adopting one or more new configurations early, and 
moving into a perfectible system apace, much as many non-federal institutions 
are doing with rich rewards.

The Task Force observed multiple symptoms of institutional stress at the national 
laboratories, including the following:



	-Increasing overhead cost, poor morale and gross inefficiencies as a 
result of overly prescriptive Congressional management and excessive 
oversight by the Department;
		
	-Inordinate internal focus at every level of these laboratories on 
compliance issues and questions of management processes, which takes a 
major toll on research performance;
		
	-Excessive scrambling by the laboratories to establish programmatic 
activities in  new mission  areas, at the expense of disciplined focus on 
traditional assignments in national security, energy, waste management 
and environmental quality, and fundamental science;
		
	-Confusion regarding the appropriate character, scope, and scale of 
laboratory collaborations with the private sector, due to a lack of clear 
policy guidance from the Department;
		
	-Institutional fragmentation as a direct reflection of segmented 
management of the laboratories by the Department, which treats the 
laboratories not as integrated institutions -- let alone a system of laboratories 
-- but rather as a conglomerate of hundreds of individual projects, each of 
which has a program manager with independent influence on elements of 
the laboratories;
		
	-Financial and institutional burdens on the laboratories as the result of an 
apparent inability by the Department either to downsize facilities which 
have excess capacity or to terminate programs which provide neither 
distinctive nor essential contributions to the national research and 
development enterprise; and,
		
	-Management systems at the laboratories that do not exhibit best 
business practices, and thus compound the management challenges of 
these complex institutions.



The Task Force recognizes that many of the Department’s laboratories are 
considered to provide some of the highest quality R&D among the federal 
laboratory system.  With this understanding, the Task Force had the option of 
simply concluding that the problems facing the national laboratories were simply 
a fact of life of federal governance and that little more could be expected.  The 
Task Force has no comfort with such an assessment, feels that it is reasonable, and 
indeed necessary to have much higher expectations for performance from these 
institutions, and believes  that incremental solutions will not likely provide the major 
improvements that are, at once, achievable and necessary.

We arrived at this conclusion recognizing that conventional wisdom likely would 
provide a range of reasons why establishing a new system of governance for the 
laboratories might be impractical or jeopardize these assets.  In our view, however, 
the long-term quality and effectiveness of these laboratories already is in serious 
jeopardy, owing to patterns of management and organization that have grown in 
complexity, cost, and intrusiveness over a long period.  For those who have been 
long time employees, managers, or observers of the national laboratory system, 
perhaps it is easy to rationalize that the system in place is simply the way it is and 
the way it always will be.   For those without lengthy associations with the 
Department or its laboratories -- which was the case for a majority of the Task 
Force members -- it is hard to reach any conclusion other than that the current 
system of governance of these laboratories is broken and should be replaced with 
a bold alternative.  The Task Force seeks not to be bold for boldness sake, but 
because it believes that a far more effective system of governance is necessary.

While this report provides a general description for a not-for-profit framework for 
governance of the laboratories, we do not presume to know what the precise 
alternative architecture should be.  That can and should be developed by 
Congress, the Department, and the laboratories, based on experience gained 
from existing research institutions which receive substantial funding support from 
the Federal Government, but which have an independent management structure 
which makes the decisions on how best to deliver the services which the 
Government is procuring.  Insight also should be gained from the experiences of 
other nations, including the United Kingdom, which recently has maneuvered a 
disengagement of several of its government laboratories into a semi-privatized 
status.

A major experiment implementing wholly new management practices for the 
national laboratories does invite risks, and certain hazards must be recognized and 
guarded against within any implementing legislation.  For example:


		
	-Those national laboratories that work on nuclear weapons programs 
may not be appropriate candidates for transfer to a non-federal 
governance structure, especially given the need for continued stringent 
controls on all aspects of nuclear weapons design activities.  Some Task 
Force members think they are.  Some think they are not.
		
	-The proposal to introduce a bold new paradigm for governance of 
these institutions must not be used as a political pretext to dismantle or 
destroy a system of laboratories which has served the nation well in the past, 
are continuing to perform important public functions, and holds the 
prospect for delivering new scientific insights and technological innovations 
which will justify its continued value to the Nation.
		
	-Protection must be built into the governance structure to ensure  that 
these institutions continue to perform long-term, fundamental research -- 
which is among their most distinctive contributions to the nation -- and not 
be driven to a short-term focus characteristic of  job shops  for the private 
sector.  This goal could be reached through prescribed allocations which 
provide an inviolate base of federal funding support for certain critical areas 
of fundamental research and their associated large research facilities.
		
	-It will be necessary to ensure that the change in governance is 
structured in a fashion to achieve the desired results, and that the new 
system not be burdened by creeping micromanagement, non-productive 
oversight, and institutional fragmentation which characterizes the present 
state of affairs at the national laboratories.
		
	-A balance must be achieved between the need for necessary 
continuing oversight and reduction of environmental damage on the one 
hand, and the need for avoiding overwhelming the new organizations with 
excessive burdens and inherited environmental responsibilities on the other 
hand.
		



D.	Configuration of the Laboratories

The Task Force believes that the national laboratory system is oversized for its 
current mission assignments.  This appears to be the result of inefficiencies that 
stem from the current management practices of the laboratories and the DOE; 
excess capacity in areas associated with nuclear weapons design and 
development; and political considerations which have inhibited downsizing and 
laboratory restructuring.  The Task Force believes that the national laboratory 
system serves many vital functions, but that the system could be productively 
downsized (or  rightsized ) through the elimination of functions and redundancies.  
The Task Force further believes that one goal of any downsizing should be 
enhanced focus on specific mission assignments.  Through downsizing, there may 
be opportunities in the future to convert one or more multi-program laboratories 
into institutions dedicated to only one primary mission.

The Task Force strongly believes that the laboratories should work more closely as a 
system, with the goal of achieving enhanced coordination and integration of 
complementary strengths.  However, we note that such coordination will be made 
more difficult to the extent that the laboratories are separated into independently 
operated not-for-profit organizations.

While the Task Force does not make any recommendations about the possible 
closure of specific laboratories, we have a general view that all of the national 
laboratories should be subjected to a regular process of comparative validation 
against other research performers (including against each other) to judge options 
for closure, consolidation, and even expansion of programmatic activities and 
facilities.   The Task Force believes that an alternative structure of governance for 
the laboratories that achieves greater independence of the laboratories from the 
Department would invite enhanced pressures for competitive performance, which 
would lower costs, force the elimination of  redundancies and less than world-class 
capabilities, and achieve enhanced value for the public investments involved.





II.The National Security Role




A.	Introduction and Background

	1.	The Changing Environment



The Department of Energy's national security mission is based on the 
Manhattan Project, the development of nuclear weapons during and 
following World War II.  The legacy includes independent design capabilities, 
redundant design teams, competition, and intense efforts to achieve the 
highest standards of safety, surety and reliability.  The three weapons 
laboratories --  Lawrence Livermore, Los Alamos, and Sandia National 
Laboratories --  have evolved over a period of more than fifty years.  It is 
clear that they played a key part in the successful outcome of the nuclear 
standoff with the former Soviet Union.  For this, the entire nation owes a debt 
of gratitude to the women and men of these laboratories, past and present, 
who gave their talent to this successful endeavor.

The end of the Cold War has brought substantial change.  Weapons 
modernization, arms control agreements, the fear of proliferation of 
weapons of mass destruction, and the significant decline in defense 
spending require a restructuring of the laboratories' support for the national 
security mission.  Today, these laboratories represent an extraordinary 
national resource of people, facilities, and experience.  Every attempt 
should be made to use this resource as missions change.


2.	National Security Requirements

The requirements for the DOE and the weapons laboratories are based on 
Presidential direction as approved in the Nuclear Stockpile Document and 
other Presidential Decision Directives.  Congress provides direction in laws 
and committee reports.  The Department of Defense (DOD) determines 
specific weapons requirements and the Department of Energy determines 
how to fulfill those requirements.  The weapons laboratories then are 
assigned specific responsibilities and funding to carry out DOE direction. 

The President stated in the National Security Strategy (July 1994) that a safe, 
secure and reliable U.S. nuclear deterrent remains a cornerstone of U.S. 
national security policy.  The President announced a moratorium on 
underground nuclear testing with a goal of establishing a comprehensive 
test ban.  He instructed the DoD and DOE to explore means other than 
nuclear testing to maintain confidence in the safety, reliability and 
performance of the weapons stockpile.  He also directed strong efforts to 
support the Non-Proliferation Treaty and counter weapons of mass 
destruction.  This direction is the basis for DOE and DoD planning for the 
future and the Task Force's consideration of alternate futures for the 
weapons laboratories.

The maintenance of a safe, secure, and reliable stockpile, contributions to 
critical proliferation and treaty issues, and participation in other national 
priorities related to this mission are essential parts of the nuclear weapons 
laboratories' future and require adequate facilities, motivated and capable 
people, and the requisite budget.  This future will require new types of 
management, different technical personnel, and a mode of operation that 
is closer to industry's than the laboratories have practiced in the past.


 



3.	Specific Weapons Requirements



The Department of Defense conducted a Nuclear Posture Review , approved by 
the President, to determine future nuclear forces and weapons requirements. 
Implementation of the START I and START II protocols will result in a total nuclear 
weapons reduction of 79% by the year 2003.  As a unilateral action (Presidential 
Nuclear Initiatives I and II), the U.S. will reduce by 90% non-strategic nuclear 
weapons.  These steps will result in a required stockpile of around 5000 weapons.

The Nuclear Posture Review identified the need for flexibility either to accelerate 
the drawdown if both sides implement START II more quickly, or the ability to return 
inactive weapons to service if the Russians suspend or delay START II 
implementation.  The weapons laboratories need the capability to respond to 
either circumstance.

Over the past two years, the Department of Energy has established the Science-
Based Stockpile Stewardship Program, replacing a test-based stockpile 
stewardship, to maintain confidence in nuclear weapons without nuclear testing.  
The focus of the new program includes improving experimental capabilities, 
enhancing computational capabilities, advanced stockpile surveillance, 
advanced manufacturing and materials capability, maintaining system 
engineering and infrastructure and preserving a nuclear design and 
experimentation capabilities.


B.	Main Findings and Recommendations

Specific recommendations regarding the future of the weapons laboratories fall 
into broad categories of mission, key personnel, configuration, peer review, basic 
science, research facilities, and weapon production (including research, 
production, tritium, and management).  The Task Force believes that these 
recommendations are consistent with Presidential Directives,   the Nuclear Policy 
Review, and the Science-based Stockpile Stewardship Program.




1.	Mission



The national security mission of the weapons laboratories has been rearticulated 
to emphasize maintaining credibility in the U.S. nuclear stockpile in the absence of  
explosive testing of nuclear weapons.  The primary mission of the weapons 
laboratories must be a safe, secure, and reliable stockpile. Science-based 
stockpile stewardship (in comparison to a test-based stockpile program) is the 
approach chosen by the Department of Energy to achieve this mission.  It requires 
the following rank-order priorities for the core functions of stockpile stewardship as 
follows:

1.	Attracting and retaining skilled scientists, engineers, and managers over the 
years ahead with the expertise required for the complex and demanding 
stewardship role;
		
2.	Enhancing surveillance of weapons in the stockpile , during dismantlement, 
and of the nuclear materials that accumulate as a result of that dismantlement;



3.	Continuing hydrodynamic testing as required to cope with  problems;

4.	Assessing problems, reanalyzing previous data through numerical simulations, 
and developing appropriate data bases; and 

5.	Sustaining the scientific process of inquiry through experimentation.

In today's world, proliferation of nuclear and other weapons of mass destruction 
remains a major threat to U.S. national security.  Because of this threat the DOE 
laboratories' work in non-proliferation, counter-proliferation, verification, and 
intelligence support has become a major mission as well as an extension of their 
stewardship of the nuclear stockpile.  These activities are supported by the 
expertise maintained within the entire nuclear weapons infrastructure.  It is 
important that their funding be included within the core infrastructure support.  The 
Task Force notes that organizational compartmentalization within the Department 
complicates and makes difficult the appropriate inter-relationship and funding 
balance between stockpile support and non-proliferation, and recommends that 
the Department's organization reflect their importance and interdependence.




2.	Attracting and Retaining Scientists, Engineers, and Managers



The weapons laboratories' management has an important responsibility to identify 
the critical skills required for their national security mission and to manage the 
hiring and retention of key personnel accordingly.  The Task Force recommends 
that management continue to sustain a stimulating intellectual environment that 
will attract and retain the very best research and engineering staff.  This will 
require:
  	


	-Providing appropriate rewards for high performers;
		
	-Weeding out weaker performers; and,
		
	-Engendering in the research and engineering staff a sense of 
achievement, based on personal responsibility and personal accountability.






3.	Configuration of the Nuclear Weapons Laboratories



The current structure of the three nuclear weapons laboratories should be 
examined in light of the recently revised, official U.S. Nuclear Posture.  The 
Department of Energy should size its nuclear weapons laboratories support efforts 
over time to match DoD requirements.  The restructuring must be accomplished in 
ways that preserve capabilities both for reduction to lower levels of support and 
for an expansion of support should the resumption of a threat to national security 
demand it.  In addition, the restructuring must support the requirement to maintain 
confidence in the nuclear stockpile in a comprehensive test ban or under an 
extended moratorium.  The restructuring will affect primarily weapons design 
capabilities, where the largest functional redundancy exists, and specifically 
Lawrence Livermore National Laboratory (LLNL); LLNL supports only four of eleven 
weapons designs currently in the U.S.  stockpile.

The Task Force believes LLNL should retain enough nuclear weapons design 
competence and technology base to continue its activities in non-proliferation, 
counter-proliferation,  intelligence support, and verification, to provide 
independent review for several years while alternative approaches to peer review 
are developed (see  Peer Review ), and to participate in weapons relevant 
experiments on the National Ignition Facility (NIF).  LLNL would transfer, as cost-
efficiency allows, over the next five years its activities in nuclear materials 
development and production to the other design laboratory.  LLNL would transfer 
direct stockpile support to the other weapons laboratories as the requirements of 
science-based stockpile stewardship, support of the DoD nuclear posture, and the 
status of test bans allow.  Under these conditions, the Task Force believes that the 
transfer can be made in five years.  The Task Force notes that if the NIF is built at 
LLNL, this will reinforce the weapons design capability at that laboratory.




4.	Peer Review



The Task Force believes that the development of independent assessment of the 
safety and reliability issues within an aging stockpile will be an ongoing 
requirement of stockpile stewardship. It also believes, however, that there are 
many ways in which this peer review function can be served, and that peer 
review, in and of itself, does not justify the existence of two nuclear design 
laboratories.




5.	Contributions to Basic Science



As new facilities are developed at the weapons laboratories for performing 
science-based stockpile stewardship, the Task Force recommends that these 
facilities be managed in as open and collaborative a fashion as national security 
constraints will permit.




6.	Major Research Facilities



The Task Force recommends the following: 



	-Continued funding support for the Dual-Axis Radiographic 
Hydrodynamic Testing (DARHT) facility;
		
	-Continued near-term support for Los Alamos Neutron Scattering 
Experiment/Los Alamos Meson Physics Facility (LANSCE/LAMPF);
		
	-Continued pursuit of advanced computing, including computing 
through workstation networks; and,
		
	-Proceeding with the National Ignition Facility (NIF) as a research facility, 
prioritized with respect to other major research investments.



In its favor, NIF will provide a unique means for doing very important experiments 
involving extremely high temperatures in condensed matter physics and it thus will 
make it possible to maintain expertise in one of the areas of physics fundamental 
to modern nuclear weapons design.  Similarly, the data and theory it will produce 
will contribute uniquely to science generally and to  astrophysics in particular.  On 
the other hand, there is some possibility that NIF will inadequately simulate 
secondaries, although this is already a lower priority than understanding primaries.  
There is a low probability that inertial fusion will become a useful source of energy 
in the foreseeable future.  NIF may not attract the scientists and engineers that 
stockpile stewardship really needs.  NIF may also complicate discussions at the 
Non-Proliferation Treaty review conference and negotiations of a Comprehensive 
Test Ban Treaty. In short, NIF is a risk (as are most major research projects), but on 
balance the Task Force supports its construction.  An important consideration is 
that the question of whether or not NIF is built at LLNL, when combined with other 
recommendations for change given in this report and elsewhere that could define 
the future of that laboratory.




7.	Non-Nuclear Research Requirements



The Task Force recommends that non-nuclear research activities continue at the 
weapons laboratories as long as a paying customer requires them, as they are 
rooted in nuclear weapons research, contribute to core R&D, and pay their fair 
share of overhead and basic research support.




8.	Nuclear Weapons Production Capacity



There is no need for nuclear weapons production at this time nor is start-up of 
production envisioned for problems expected in the stockpile. Capability-based 
deterrence requires, however, the potential for weapons production in the event 
of increased threat that may arise in the future.  The current world situation and 
the existing production capability do not mandate investment in additional 
production capability.  The Task Force recommends that future production should 
be based on the residual capabilities of Pantex, Los Alamos National Laboratory, 
and Sandia National Laboratories, and believes that no further investments in 
production capability are needed at this time.




9.	Tritium Supply



Accelerator-based production of tritium looks attractive, given today's 
understanding of the technology.  The Task Force, however, does not make a 
recommendation relative to replacement, or to the mode of production, but 
rather supports continued R&D in accelerator-based production of tritium.




10.	Management of the Nuclear Weapons Laboratories by DOD


As requirements for national security change, DoD and DOE must size their 
organizations and improve their coordination for maximum effectiveness.  The DoD 
must act as an intelligent and prudent customer regarding nuclear weapons.  The 
separation, within the U.S. government, of nuclear weapons development and 
operations is a long tradition and has recently been challenged in the interest of 
efficiency.  The Task Force, however, agreeing with most previous studies of this 
issue, sees no compelling reason for DoD to manage the national security activities 
at the weapons laboratories.  Indeed, the Task Force believes that there is much 
value at this time in maintaining an independent and technically expert 
organization to focus on nuclear stockpile issues and to continue to ensure that 
decisions regarding the safety, control, and stewardship of nuclear weapons are 
raised to the high policy level that they deserve.  The corporatization proposal 
contained in  Section VII in the Task Force report could eliminate the management 
issues for both DoD and DOE and give a customer focus to the weapons 
programs.


C.	Summary of Recommendations

1. The primary mission of the weapons laboratories must be a safe, secure and 
reliable nuclear stockpile in the absence of explosive testing.  Science-based 
stockpile stewardship is the approach chosen be the Department to achieve this 
mission.  It requires the following rank-order priorities:
	


-	Attracting and retaining skilled scientists, engineers, and managers over the 
years ahead with the expertise required for the complex and changing 
stewardship role;
	
-	Enhancing surveillance of weapons in the stock pile, during dismantlement, 
and of the nuclear materials that accumulate as a result of the dismantlement;
	
-	Continuing hydrodynamic testing to cope with problems;
	
-	Assessing problems, reanalyzing previous data through numerical 
simulations, and developing appropriate data bases; and
	
-	Sustaining the scientific process of inquiry through experimentation.


	
2.	Non-proliferation, counter-proliferation, verification, and intelligence support 
have become a major mission along with stewardship of the nuclear stockpile.  
The Task Force notes that organizational compartmentalization within the 
Department complicates and makes difficult the appropriate inter-relationship 
and funding balance between support and non-proliferation, and recommends 
that the Department's organization reflect their importance and 
interdependence.
	
3.	The Task Force believes Lawrence Livermore National Laboratory should retain 
enough nuclear weapons design competence and technology base to continue 
its activities in non-proliferation, counter-proliferation, verification, an intelligence 
support, to provide independent review for several years while alternative 
approaches to peer review are developed, and to participate in weapons 
relevant experiments on the National Ignition Facility (NIF).  Lawrence Livermore 
National Laboratory would transfer as cost-efficiency allows over the next five 
years its activities in nuclear materials development and production to the other 
design laboratory.  Lawrence Livermore National Laboratory would transfer direct 
stockpile support to the other weapons laboratories as the requirements of 
science-based stockpile stewardship, support of the DoD nuclear posture, and the 
status of the test bans allow.
	
4.	The Task Force recommends continued funding support for the Dual-Axis 
Radiographic Hydrodynamic Testing (DARHT) facility; continued near-term support 
for the Los Alamos Neutron  Scattering Experiment/Los Alamos Meson Physics 
Facility (LANSCE/LAMPF); continued pursuit of advanced computing, including 
computing through workstation networks; and proceeding with the National 
Ignition Facility (NIF) as a research facility, balanced with respect to other major 
investments.
	
5.	The Task Force recommends that future production needs should be based on 
residual capabilities of Pantex, Los Alamos National Laboratory, and Sandia 
National Laboratories, and believes that no further investments in production 
capability are needed at this time.





III.The Energy, Environment, and Related Sciences and Engineering 
Role



A.	Main Findings

This section of the report reviews the laboratories' energy and environmental roles 
(minus activities associated with clean-up of waste sites, which are dealt with in 
Section IV), and includes the Task Force's general observations about missions of 
the laboratories.




1.	The Energy Mission of the Laboratories



The national laboratories have an important energy mission which, in the view of 
the Task Force, remains absolutely vital to the national security and economic 
welfare of the nation.  This mission started with the efforts to create peaceful uses 
of nuclear energy (a major goal of the civilian Atomic Energy Commission) and 
assumed new direction and urgency as a result of the  energy crises of the 1970s.  
The 1973 oil embargo prompted Congress the following year to create the Energy 
Research and Development Administration (ERDA), folding together nuclear 
programs from the Atomic Energy Commission (AEC), fossil energy and utility 
distribution programs from the Interior Department, solar and geothermal 
programs from the National Science Foundation, automotive propulsion programs 
from the Environmental Protection Agency, as well as several other dispersed 
functions.   Although the Energy Research and Development Administration 
(ERDA) was to be a transitional agency, replaced by the Cabinet-level 
Department of Energy in 1977, progress was made in bringing together diverse 
energy activities previously scattered among many federal agencies.  One legacy 
of the Department's origins, however, is that the different areas of energy supply 
and end-use R&D remain balkanized--operating as isolated fiefdoms.  Additionally, 
the Department's applied energy programs are not well integrated with either the 
Department's environmental or basic science programs.

The Task Force believes that one of the most important challenges facing the 
Department and its laboratories is to achieve greater integration of its various 
applied and fundamental energy R&D programs (i.e. fossil energy, nuclear fission 
and fusion, energy efficiency, renewable energy, and basic energy sciences).  
The integration that is necessary should be both internal, into a portfolio of 
programmatic activities organized according to a common framework of policy 
objectives, and external, including both cross-governmental, and Department-
private sector initiatives.  In the Task Force's view, there is a long list of exciting, 
challenging, and vital areas of research and technology development that 
constitute the appropriate energy agenda for the laboratories.

It is important to note that the Department's applied energy programs are 
executed in a variety of ways, including at the laboratories, both with and without 
industry cost-shared involvement; directly between the Department and industry, 
through cost-shared collaborations; and directly with universities.  Of the 
Department's FY 1994 applied energy budget of roughly $1.8 billion, only 30 
percent is expended at the laboratories.  The Task Force recognizes that another 
group of the Secretary of Energy Advisory Board is examining the applied energy 
programs;  however, in the  course of our examination we did develop firm views 
about the energy mission both at the Department and the laboratories.

In general, the Task Force believes that the energy mission is of extreme 
importance and deserves greater attention by the national laboratories, working 
in collaboration with the private sector.  Additionally, we believe that the 
Department needs a framework for rationalizing the management of energy 
supply and conservation technologies in terms of a strategic portfolio of research 
and development projects.

National and Global Energy Needs

During the next 20 years, world energy demand will grow by 50 percent.  Most of 
this growth will occur in the developing world, where energy is perhaps the single 
most important factor for economic expansion and enhanced quality of life.  
Given the environmental impacts of current modes of energy use, research on 
means of enhancing the efficiency of energy utilization and on substitutes for fossil 
fuels is of critical national importance.  Although oil, natural gas, and coal will 
remain the dominant energy source in the world for the next 20 years -- still 
providing as much as 80% of the global energy supply in the year 2015 -- the 
development of clean, sustainable, alternative forms of energy will be essential as 
projected fossil fuel supplies dwindle and environmental constraints mandate a 
dramatic switch in fuel sources during the next century.  The global market for 
clean energy sources could be in the hundreds of billions of dollars 20 to 30 years 
from now, yet the R&D involved is of a sufficiently high-risk and long-term nature, 
and the public purpose of this research is sufficiently compelling, that it properly 
should be addressed through collaborative work between the public and private 
sectors.

The Task Force generally believes that the highest priority research areas by the 
Department and the laboratories are in the areas of energy efficiency, 
conservation, renewable energy sources (including photovoltaic, biomass, wind, 
geothermal, and hydrogen), and more efficient recovery of gas and oil resources.  
The laboratories should also continue to be involved in nuclear fission-related R&D.  
The Task Force was divided concerning a recommendation for the level of support 
needed in the area of fusion energy.  At a broader level, the Task Force believes 
that the Department's energy programs should be managed more as a portfolio 
of investment areas, giving appropriate attention to the diverse and sometimes 
conflicting goals in various areas of energy supply and conservation R&D.  These 
goals must be balanced with the overall energy objectives of the Department -- 
which must be based on the national goals for energy development and 
utilization.

These goals must be coordinated closely with the energy supply industry, with 
makers and users of energy conservation technologies, and with other 
stakeholders to develop a meaningful strategic plan for investments in energy 
supply and conservation technologies.  This is the most important single aspect of 
the rationalization of the energy R&D work of the Department.  A consensus must 
be developed among potentially competing technologies, users, and 
stakeholders that defines the R&D needs of the nation in  sufficiently explicit terms 
that conclusions can be drawn to guide the implementation of a rational R&D 
strategy.

Alliances with the industrial users of the technology will be critical.  R&D produces 
knowledge, but the implementation of that knowledge in plants and products 
must be done by industry.  If industry is not intimately involved in the planning and 
development of that knowledge, they will be slow to implement it if they do so at 
all.  The Department currently has several major collaborations in place with the 
Gas Research Institute, Electric Power Research Institute, fossil fuel extraction 
companies, and energy-intensive industrial sectors, such as the pulp and paper 
industry.  The Task Force commends these efforts, which help guide appropriate 
areas of government vs. private sector R&D, and help ensure eventual 
commercialization of new technologies and processes.

The Task Force recognizes, however, that the energy mission of the Department is 
broader than the interests of the existing private sector in important ways.  For 
example, both energy producing and energy using industrial sectors will have an 
inevitable bias toward existing technologies and infrastructure, and a relatively 
short-term outlook.  The Department, on the other hand, must consider the long-
term energy and economic security of the nation, which are closely linked.  
Accordingly, the Department must be careful to ensure that, while working closely 
with energy producers and users, its energy R&D program is not captured or 
dominated by short-term interests, since the most appropriate areas for laboratory 
investment using public funds will be in areas which address long-term 
uncertainties and needs.

Within the portfolio concept, each area of energy technology, and indeed 
potentially each R&D project, should be evaluated in terms of four key elements:



	-Technological strength;
		
	-Technological maturity;
		
	-Competitive impact on public objectives (i.e., energy, efficiency, 
energy diversity, environmental protection, economic impacts, cost); and,
		
	-Risk.



Section VI of this report provides additional considerations regarding the 
development of applied energy work at the laboratories.



2.	The Environmental Mission of the Laboratories



The DOE laboratories have a diversified environmental mission, which includes two 
traditional areas of activity and one emerging area.  The traditional areas are 
science and technology development associated with the clean-up of nuclear 
waste (addressed in Section IV), and R&D related to assessing the environmental 
impacts of energy use (e.g. global climate modeling, atmospheric chemistry).  The 
emerging area involves systemic approaches to reducing energy and materials 
consumption in specific industrial applications -- such as environmentally-conscious 
manufacturing -- and also for entire segments of the economy.

In Technology for a Sustainable Future , the Administration has presented an 
integrated vision of long-term economic growth that creates jobs and protects the 
environment.  Environmental technologies -- ranging from clean energy sources to 
energy efficient manufacturing techniques to industrial processes that create new 
products from waste materials to the development and use of new energy 
efficient materials -- are viewed as the means of helping industry shift from waste 
management to pollution prevention and efficient resource utilization, and a 
critical step toward implementing industrial ecology.  This would enable 
companies to enhance their competitiveness by lowering energy and resource 
needs and reducing or eliminating waste disposal costs, and benefit the nation by 
reducing the environmental impact of economic activity.

The Department of Energy national laboratories should play a significant role -- in 
collaboration with energy- and material-intensive industries -- in the development 
of environmental technologies and an enhanced understanding of resource 
utilization in the economy.  The concept of "industrial ecology" has begun to take 
root within the private sector as a way to examine energy and materials flows for 
industrial systems, products, and services, with the objective of providing a systems 
approach to designing environmental compatibility and sustainability of those 
systems.  The scientific and technological capabilities needed to advance our 
understanding of energy and material use in the economy, in an industrial 
ecology framework, include:



	-Energy supply, distribution, and end-use science and technology;
		
	-Advanced manufacturing and process technologies;
		
	-Materials science and technology;
		
	-Environmental science and technology; and,
		
	-Modeling and simulation of complex systems.


These capabilities are broadly resident in the Department’s national laboratories 
and are already being applied to a number of projects that hold the potential for 
substantial improvements in resource utilization by various industrial sectors.  For 
example, in the general area of manufacturing and process technology, projects 
at the ten laboratories amount to more than $100M/year in FY 1994.

The Task Force believes that the laboratories could, and should, make a significant 
contribution to the integration of energy, raw materials, technology and 
environmental science throughout the nation's economy, and the development 
of the field of industrial ecology.  However, at this point neither the Department or 
the laboratories are organized or managed to support this R&D area.  
Accordingly,  we encourage the Department, working with the laboratories, to 
develop an integrated plan, based on the portfolio  concept, for supporting this 
important area of research.  We encourage the Department, as part of this effort, 
to establish an Industrial Ecology Advisory Board, including members from the 
laboratories, state, private industry, public interest groups and other government 
agencies.

We do not see this as a new mission area for the laboratories, but rather as an 
extension and integration of existing missions in energy and environmental quality.  
In fact, the Task Force believes that, without developing additional capabilities in 
environmental technology and industrial ecology, it will be difficult for the 
Department to carry out either its energy or its national security mission, such 
capabilities will augment and add value to the primary missions of the Department 
and laboratories, rather than being a new mission in itself.  In addition, although 
the Task Force believes that there exists considerable potential within the 
laboratories to contribute to the development of environmental technology and 
industrial ecology, we recognize that R&D performers in academia, industry, and 
other government agencies also have significant roles.  The level of support to the 
laboratories should be determined solely by the quality of performance and the 
comparative advantage of these institutions in addressing complex technical 
challenges involving energy and resource utilization.



3.	General Observations About Laboratory Missions



Over the past two decades, several studies of the Department of Energy's 
laboratories have observed that these laboratories do not have clear mission 
assignments which would enable them to remain tightly focused on specific 
national priorities and programmatic goals.  This Task Force found a continuing 
lack of mission-derived structure both within the individual national laboratories, 
and across the system of ten laboratories which were the subject of this review 
(although the phenomenon is less pronounced at the three weapons 
laboratories).   The multi-program laboratories currently have self-generated 
mission descriptions which are so broad and generalized that they are essentially 
indistinguishable.  As such, it appears that each laboratory is attempting to keep its 
options open in all fields of science and technology, which is compounding the 
problems of effective management.  Researchers at the laboratories feel a sense 
of drift in no small part because the laboratories do not have sufficient focus or 
clarity of purpose.
The Task Force believes that diffuse mission assignments for the national 
laboratories may have been politically acceptable and fiscally affordable during 
the Cold War, but do not meet the political, budgetary, management, and 
programmatic needs of the present and future.  At the same time, the Task Force 
recognizes that there are important and practical limitations on how narrow one 
can be in delineating missions for multi-program laboratories which exhibit vast 
breadth both in technical expertise and programmatic activities, and whose 
uniqueness in large degree derives from an ability to support complex, multi-
disciplinary R&D activities.   Such limits also stem from the inherent difficulty of 
assigning goal-oriented missions to institutions which perform a considerable 
amount of basic research -- activities which the Task Force believes are essential 
for the nation, but for which the timing and nature of discoveries is fundamentally 
unknowable.

 The Task Force did not elect to take on the task of suggesting specific areas of 
programmatic focus for each of the national laboratories.  However, we do feel 
strongly that the Department and the laboratories -- working together -- must go 
much further than they have to-date in developing mission assignments for these 
laboratories which will balance both the strength of these institutions as multi-
program laboratories with the need to provide greater strategic focus within a 
tight federal budget environment.  Such mission descriptions, which should help 
guide funding decisions by the Department, should:



	-Capture the primary focus or strategic thrust of each laboratory, while 
also identifying the two or three areas of secondary importance based on 
specialized capabilities;
		
	-Reflect areas of distinctive competence;
		
	-Provide the basis for organizational coherence and motivation; and
		
	-Be sufficiently clear and specific to enable the development of goals 
against which performance can be evaluated.



The Task Force believes that the development of more refined mission statements 
for the laboratories, disciplined by Departmental budget decisions and strategic 
planning, will result -- over time -- in greater differentiation and specialization 
among these institutions.  One mechanism for institutionalizing this specialization 
could be, for example, the creation of a number of  Centers of Excellence  within 
the laboratory system.  This will have the beneficial affect of ensuring that the 
critical mass of programmatic focus in various mission areas will be secured within 
the confines of individual institutions, rather than being dispersed at sub-threshold 
levels across the entire system of laboratories.  It also will provide the basis for 
programmatic consolidation and elimination of functional activities which are  
being performed better elsewhere in society.

The basis for public support of the national laboratories is:  1) that they are 
locations for centralized, generally large-scale R&D facilities that could not be 
maintained by academia or the private sector,  and 2) they perform R&D for 
which there is a strong public purpose (e.g. national defense and complex, long-
term research), and which for reasons such as market failures or other deficiencies 
in the national R&D infrastructure, the highest quality performance is through 
federal funding for these institutions.  The basic mission of these laboratories should 
be to strive for quantum advances in our knowledge base, and to work with other 
R&D performers to transition such knowledge into applications that meet national 
needs.  One of the great strengths of the multi-program laboratories derives from 
the diversity of technical expertise that can be brought to bear from within these 
laboratories on specific scientific and technical challenges.  In recommending 
that more specific missions be assigned to the laboratories, therefore, the Task 
Force seeks not to force specialization that would fundamentally jeopardize the 
multi-attribute character of these institutions.  Rather, the Task  Force is responding 
to a fundamental fiscal reality that has forced corporations and universities alike to 
concentrate on areas of strength, and to divest from areas of mediocrity.

While the Task Force believes there is considerable value to ensuring a 
concentration of capabilities at common locations, we also recognize the value 
of competition in spurring innovation (i.e. the highest quality proposals, as 
determined by peer review processes, should be the ones that are funded -- 
regardless of whether proposals to satisfy DOE mission assignments come from a 
DOE laboratory, university, or industry).   However, to-date there seems to have 
been a pattern of spreading the wealth across the multi-laboratory system rather 
than concentrating resources at individual laboratories or specific Centers of 
Excellence.

The Task Force also recognizes that there is considerable potential in achieving 
greater coordination of R&D expertise across the lab complex.  The national 
laboratories are equipped with the information technologies and the culture of 
communication via computer networks which could provide the basis for close 
programmatic integration.  The Task Force believes that the goal of efficiency in 
utilization of the national laboratories mandates that these institutions be 
managed better as a system, and that complementary strengths be integrated to 
the extent possible through the establishment of "virtual laboratories" via computer 
networks and lead laboratory assignments.  As the laboratories are given more 
discrete missions which result in enhanced R&D focus, the creation of "virtual 
laboratories" will be an important means for retaining complex, multi-disciplinary 
approaches to problem solving across the laboratory system.


B.	Recommendations




	1.	The Department should organize itself to achieve greater integration among 
its applied energy programs, between these programs and industry, and 
between the applied energy and basic energy research work performed at 
the laboratories.  The Department's applied energy work does not appear to 
be managed as a portfolio, rationalized and integrated under a common 
strategic framework; rather, it operates like disparate fiefdoms.  Greater 
coordination could be achieved through planning efforts that apparently 
do not now exist.
		
	2.	The integration of energy and environmental considerations should be a 
fundamental organizing principle for much of the Department's activities.  
Energy production and use, environmental protection, and economic 
output are increasingly interrelated, and the Department--through its 
laboratories--have substantial technical resources to address these national 
needs in an integrated fashion.  At the present time, however, neither the 
Department nor its laboratories are organized to meet the potential that the 
Task Force believes exists to further the development of environmental 
technologies that meet the shared needs of energy, environment, and the 
economy.  The Department should continue and expand R&D partnership 
efforts between the laboratories and resource-intensive industries, utilizing 
the concept of industrial ecology as a method for deriving outcomes  that 
contribute to sustainable economic development.   An Industrial Ecology 
Advisory Board should be established to support this effort.
		
	3.	The Department and the national laboratories should move promptly to 
establish clear mission statements for the laboratories which will be utilized as 
tools for budget decisions and long-term strategic planning.  The process of 
establishing missions for the laboratories should be exploited as an 
opportunity to clarify the precise character of the world-class strengths 
within each of these institutions, as well as the areas which may be 
appropriate for downsizing, elimination, or consolidation elsewhere within 
the laboratory system.
		
	4.	Mechanisms should be established to enhance the management of the 
multi-program laboratories as a system.   The Department should develop a 
means of breaking the existing pattern of laboratory management, which 
treats each lab as a conglomerate of hundreds of individual programs, and 
all of the laboratories as separate and distinct entities.  Greater efforts 
should be taken to coordinate and integrate the complementary strengths 
of these institutions through communications networks.  In addition, 
institutional arrangements should be established to facilitate joint planning 
by the full group of multi-program laboratory directors and senior 
Departmental officials.
		
	5.	The Department should establish lead laboratories according to mission 
assignments and programmatic strengths.  The current management of 
programs by the Department from headquarters promotes the existing 
balkanized structure of program execution.  Lead laboratory designations 
would vest substantial management responsibilities closer to where the work 
is performed, while leaving Departmental program managers with the job of 
focusing on research needs, mission success, and long-range strategic 
policy.
		
	6.	The Department should establish Centers of Excellence within the laboratory 
system.  These should reflect specific high priority national and Department 
research needs, and can be either wholly within one laboratory, or a  virtual 
Center of Excellence,  drawing upon the resources of several laboratories.  
In this way, specialization while retaining broad multidisciplinary capabilities 
can be encouraged.





IV.The Environmental Cleanup Role



A.	Introduction

The Department of Energy's management of its program for dealing with the 
radioactive and hazardous wastes at its former nuclear weapons production sites 
and the national laboratories has been criticized for its expense and the slow 
pace of cleanup.  The program is of great size and the problems that plague it, 
developed over decades, are acute and pervasive.  Involving the national 
laboratories in more sweeping ways is an important part of a number of needed 
improvements.


B.	Background

Disposal practices for radioactive and chemically hazardous wastes from the start 
of the Manhattan Project of World War II, excepting high level waste, consisted of 
shallow burial, of injection underground using deep or shallow wells, the use of 
cribs or settling ponds, or direct release to rivers or streams.  Some of the Atomic 
Energy Commission's (AEC) practices resulted in the exposure of uninformed 
members of the general public to substantial levels of radiation and in later years 
there have been well-publicized leaks of toxic and radioactive materials.

Environmental concerns in the U.S. started rising in the 1950s, initiating a new era of 
citizen participation, and major changes, in environmental matters. Over three 
dozen pieces of Federal environmental legislation were enacted by the early 
1990s.  The AEC and later the DOE, did not move as U.S. industry did, maintaining 
that they were exempted from compliance with the bulk of U.S. environmental 
legislation.

Although beset by increasing discontent and criticism over its practices, DOE was 
slow to accommodate.  It continued its old patterns of behavior until, in 1984, it lost 
a key lawsuit brought against it.  Amendments to major pieces of Federal 
environmental legislation now explicitly require DOE compliance.  The result has 
been to make DOE subject to the same array of Federal environmental standards 
that U.S. industry had already largely adapted to.  The DOE found itself 10 years 
behind in Environmental Protection Agency (EPA) compliance.

In 1989, the Department announced that it would have all of its sites cleaned up 
by 2019.  This same year it created the Office of Environmental Restoration and 
Waste Management (since renamed the Office of Environmental Management, 
or EM) to have responsibility for cleanup of the complex. The EM annual budget 
has risen from $1.6 billion in 1989 to $6.2 billion in 1994 and will exceed $7 billion 
when the Savannah River Site is transferred to it from Defense Programs.  It has 
become the largest single item in the DOE 's $19 billion budget.  It is the largest 
environmental restoration and waste management program in the world.
Driven by heightened public and Congressional concern, DOE established, in 
some haste, greatly enhanced requirements governing its own operations.  It 
initiated major growth in the number and scope of environmental, safety and 
health regulations, nuclear safety regulations and DOE Orders.  To ensure 
compliance, the number of audits, reviews and appraisals was increased 
dramatically.
 
DOE now has had to cope with the series of legal commitments to cleanup 
performance, with milestones and penalties for non-compliance, that it signed 
with state and federal bodies, for each of its sites, Inadequate attention was given 
by DOE to the feasibility of these commitments.  One example was the Tri-Party 
Agreement at Hanford, signed by DOE, the EPA and the state of Washington's 
Department of Public Health.  It mandates cleanup of the site by the year 2019.

The Department has been hindered by the press of Federal legislation and 
regulation by other Federal bodies.  A dozen or more pieces of legislation all laid 
on DOE burdens with which it has been poorly equipped to deal.  Moreover by 
the 1990s, all the states had their own environmental legislation, much of it binding 
on the Department and not always consistent with its Federal counterpart.

The Department also is hindered by lack of credibility and mistrust, not only on the 
part of community stakeholders but by Federal and state legislative and regulatory 
bodies.  Some members of these bodies continue to disbelieve the Department, 
as well as many of its contractors, even when they are telling the truth.


C.	Main Findings




1.	Technical Challenges



The large quantities of radioactive and hazardous chemical waste that are at the 
center of concern exist in a broad variety of forms, toxicity, and storage or 
placement conditions.  For the entire 3365 square miles of the DOE complex, now 
or formerly devoted to weapons-related activities there are, for example:



	-3700 contaminated sites, 500 facilities now surplus, 1000 more which will 
be declared surplus soon, and 5000 peripheral properties with soil 
contaminated by uranium mine tailings.  DOE might declare as many as 
7000 facilities surplus in coming decades, most of which would require 
cleanup prior to decommissioning.
		
	-More than 330 underground storage tanks (including those at Hanford) 
containing 77 million gallons of high level radioactive waste as sludges or 
liquids.
		
	-Waste volumes from weapons-related activities:
		


-	High Level Waste (HLW)	385,000 cubic meters
-	Transuranic Waste (TRU)	250,000 cubic meters
-	Low Level Waste (LLW)	2,500,000 cubic meters
	
	-The LLW volume is equivalent to a cube nearly 0.1 mile 
on an edge which, if water, would weigh 2.8 million tons, if soil, 
some 8.4 million tons. The costs of disposal of low level 
radioactive waste (LLW) are currently in the vicinity of $5800 per 
cubic meter, for HLW as high as $6 million per cubic meter.


		
	-More than one million 55 gallon drums or boxes of stored,  hazardous, 
radioactive, or mixed (radioactive and chemically toxic) waste.  An 
additional 3 million cubic meters of buried waste, much having breached 
containers, is mixed with soil underground.
		
	-Over 100,000 gallons of plutonium and transuranic waste liquids having a 
high likelihood of causing environmental contamination and worker safety 
problems.
		
	-More than 5700 individual "plumes," contaminating soil and 
groundwater, have been identified on DOE lands.  For example, plumes of 
hazardous chemicals underlie about 150 square miles of the Hanford site.






2.	Program Assessment



Two yardsticks are useful in judging the EM program: progress toward cleanup 
goals and the costs incurred, the latter related to the effectiveness of program 
management.

The remediation program has accomplished far less than many wish.  The 
Government Accounting Office , in a recent review of management changes 
needed to improve applications of technology in the program, concluded that 
while "DOE has received about $23 billion for environmental management since 
1989, .. little cleanup has resulted.  Experts agree that many cleanup technologies 
in use are extremely costly and offer only short-term solutions."  A May 1994 
Congressional Budget Office (CBO) Study  noted that DOE "has been criticized for 
inefficiency and inaction in its cleanup efforts. ... [and] has been severely criticized 
because of the small amount of visible cleanup that has been accomplished."  
These conclusions are shared by many senior DOE personnel, both within and 
outside the program.

One of the consequences of the troubles has been the enhancement of a 
syndrome common to large bureaucracies: risk aversion.  It has a name: "the 
Hanford Syndrome."  It has become widespread and severe in the EM program.  Its 
symptoms are an unwillingness to alter familiar behavior patterns, to stick with 
unproductive or failing procedures, to enhance tendencies for excessive resource 
allocation and regulation, and to oppose innovation.  It is an important element in 
sustaining unproductive patterns of work.

The Tri-Party Agreement at Hanford, and similar ones elsewhere, have proven to 
constitute major constraints on remediation progress because, in many instances, 
they are unrealistic, not having had proper input from those experienced in actual 
cleanup.  The milestones they incorporate, along with penalties for 
noncompliance, force continued activities, some of which are make-work and 
should be abandoned.  Other activities should be delayed or modified so as to 
await more effective and less costly technologies.   Virtually no one believes the 
timetables are achievable and DOE has already been forced into renegotiations, 
as at Hanford in January 1994.  Elsewhere DOE has been paying fines, owing to 
the Department's incapacity to meet deadlines, as at Rocky Flats where $27 
million is now due for missing cleanup deadlines.

Probably the most important reason behind the slow pace of  assessment and 
cleanup is the low quality of science and technology that is being applied in the 
field.  Many of the methods, such as "pump and treat" for contaminated ground 
water remediation, cannot provide the claimed benefits.  There is a lack of 
realization that many_--_ and some experts believe most_--_ existing remediation 
approaches are doomed to technical failure.  Others would require unacceptable 
expenditures and much extended time to reach their stated objectives.

Over time, an increasing proportion of DOE resources has been going into DOE 
management in an attempt to lower environmental costs.  The Congressional 
Budget Office report concluded that "at least 40% of the cleanup program's funds 
are devoted to administrative and support activities, a level that many reviewers 
have considered excessive. ...[they] represent a proportion that is significantly 
higher than the share spent by some other government agencies that may be 
performing similar tasks." 

DOE provides the most expensive environmental services of any government 
agency, with costs 40% above the average in the private sector.  When DOE first 
became aware of these high costs, the Department's response was to try to lower 
them by an increase in management attention: it added between 1200 and 1600 
Full Time Equivalents to its management and oversight personnel overseeing the 
remediation program.

How much the program will cost when and if completed cannot now be assessed 
with confidence.  Estimates in the range $300 billion to $1 trillion have been made 
by DOE officials, but a lack of specific goals and achievable schedules as well as 
the absence of some critical remediation technologies make fixing the sum 
difficult.  Some part of the facilities' contamination cannot be wholly cleaned-up; 
portions of the Hanford site, as well as others, will still be radioactive after many 
thousands of years.


D.	Disconnects

One useful way of understanding the nature of the problems plaguing the DOE 
program is to look at "disconnects," potentially discordant sets of activities whose 
discord the Department has been incapable of harmonizing.  There are 
disconnects in three areas of major importance to the EM program: (1) 
science/engineering and applications, (2) regulatory, oversight and compliance 
and (3) goals, objectives and means, the last involving the stakeholders affected 
by the program.  These persistent disconnects have had numerous adverse 
consequences on the program.




1.	Science/Engineering - Applications



There is a marked incapacity within the Department's EM program to evaluate 
current and prospective technologies in a wide-ranging and competent manner 
based on well-assessed risks.  Without the resulting information it is not possible to 
introduce improved technologies into the applications stream or to modify or 
eliminate inefficient or ineffective ones.  The gap between what might be applied 
and what is applied is well known within the program; it is called the "Valley of 
Death."  In part it reflects the fact that there is inadequate communication 
between those attempting to remediate the contaminated sites and the research 
community that holds the key to identifying and readying  advanced and 
powerful technologies.

One of the injurious consequences of the gap has been the failure to carry out a 
full program to characterize the waste remediation challenge across the many 
DOE sites: the nature of the risks presented by the diverse array of problem 
radioactivity and hazardous materials, the identification of applicable and 
available technologies to deal with them, as well as their limitations, and provide 
schedules, costs and expected effectiveness of reasonable and acceptable 
programs of remediation.  The laboratories have not been tasked to perform such 
a characterization although they are well aware of its lack and have the technical 
capacity to carry it out.

The new-technology chain is seriously broken within DOE.  There is little basic 
research being carried out relevant to the problems at hand and there is little 
rigorous analysis to learn from the experience in the field or from current tests. 
There is, for example, breakdown in communication and cooperation between 
organizational units within EM, from headquarters to field offices to sites.  
Technologies are being developed independent of field and site needs that are 
subsequently not field implemented because of a lack of customer interest or 
involvement or because they replicate work done elsewhere.

The root deficiency, which makes the science/engineering - applications 
disconnect a persistent problem, is the absence of a sustained, high-quality, 
scientific/technical review capability at a high level within DOE as well as a lack of 
leadership and poor management of the science/engineering - operational 
interface.




2.	Regulatory - Oversight - Compliance:  Management Disconnects



The host of self-inflicted, complex and frequently contradictory or redundant 
regulations and requirements that the laboratories and remediation efforts are 
subject to has become an enormous obstacle.  Compliance can be quite 
burdensome, expensive and frequently fails to improve the affected activities.  
The influence of this disconnect is not confined to the EM program alone.  It 
affects most every DOE activity, including those in both the multiprogram and the 
program-dedicated laboratories.  Its consequences are greatest in the EM 
program simply because this program is DOE’s largest.

In many circumstances there are harsh non-compliance provisions, and legal 
personal and civil penalties for failure.  People are intimidated, afraid of going to 
jail, and this forces an excess conservatism, sometimes bordering on inaction.  
There is no dispute that this aggravates inherent tendencies toward risk aversion, a 
problem for other reasons, as noted earlier.

The managerial defects are discussed in the Appendix and are the subject of 
Section VII.  That section should be considered an important adjunct to this present 
contribution for these defects have played an important role in causing and 
sustaining the problems in the EM program.




3.	Goals - Objectives - Means: Stakeholders Interests


 
DOE has not set out to determine, in concert with affected stakeholders, the goals 
it should pursue, nor the standards to be met in the EM program.  There is a 
disconnect with the customer base.  Are waste-contaminated soils to be 
removed, remediated, left in place?  What exactly is to be done to and with low-
level waste?  What to do about the large quantity of tritiated groundwater?  What 
site conditions are the activities at Rocky Flats intended to achieve?  No one is 
entirely sure.  The January 1994 alterations to the Hanford Tri-Party Agreement 
were, in part, a consequence of some of these issues surfacing.

One result of the disconnect is too much attention to the immediate, acute 
problems, such as possible tank leaks, explosions, overheating, with relative 
neglect of longer range difficulties.  The immediate matters can be serious, and 
must be dealt with, but the lack of a systems approach to the problems and their 
solutions, and thus lack of a synoptic view, means a poor priority list and provides 
bad choices.  All of these elements lead to much ineffectual, albeit expensive 
activities. 


E.	The Future




1.	Within DOE



A well-functioning EM program with clearly defined goals is surely within reach, 
given a Department commitment to move forward.  The model that many refer to 
was the hugely successful Manhattan Project of World War II, with its exquisite 
blend of basic and applied science underlying a large production complex, 
based on previously unknown physical phenomena.  From it emerged the testing, 
production and delivery of the weapons employed just at the end of the conflict.  
The scientific challenge today is less profound, the managerial ones more so.  A 
crisp, well-defined program, fully utilizing national laboratory skills, could prove a 
model within the Department and for the nation on how to run a major enterprise.  
We now have a poignant situation, for technology known to senior scientists and 
engineers both in the national laboratories and in the country's universities is in the 
wings that, appropriately applied, could dramatically alter the current prospects.




2.	The National Laboratories



Because the EM program so badly needs high quality science and engineering 
development, the national laboratories together have a critical role to play, a role 
very much larger than at present.  The laboratories have unique resources and 
facilities and are accustomed to the complex, interdisciplinary blend of sciences 
and technologies that are the mark of large, technically-driven enterprises.  They 
are really the only organizations that can pursue the large-scale basic research 
and development so badly needed to replace those conventional approaches 
that blight much of the current EM program.  Industrial site-contractors cannot 
carry out such tasks effectively for much commitment to basic research puts the 
meeting of compliance deadlines at risk, dangerous in today's climate.

Most of the national laboratories confront large ranges of environmental problems 
on their own sites which, while regrettable, can serve as test beds for the 
development of a broad spectrum of improved remediation, waste minimization 
and cleanup technologies  for application on far larger scales.

It may be important to designate lead laboratories for major programs to be 
established from among the laboratories to provide the synoptic view necessary 
to implementation of the scientific and technical studies and demonstrations 
necessary for a swift and efficient program.  Most all of the national laboratories 
have important contributions to make to the EM program; a lead laboratory's role 
would be one of coordination and overall systems analysis and integration for a 
particular major effort.  This does not mean assuming management responsibilities.  
The responsibilities fall to DOE  management and its contractors and should remain 
there.

An additional benefit from designation of such lead laboratories is that they could 
become test beds for improvements in DOE regulatory and management 
practices and DOE Order compliance as well as for enhanced public 
participation.  In brief, they can act as sites for valuable pilot programs, 
demonstrating the benefits of positive changes.

Formal institutional connections will be required with a number of other Federal 
bodies whose skills or whose regulatory authority relate to the tasks of the 
remediation program.  These include the Environmental Protection Agency, the 
Department of Defense, the Bureau of Mines, and others.  A lead laboratory is the 
natural place for much of this linkage to be coordinated.  Here is where special 
regulatory provisions must be hammered out so as not to hobble research and 
development work unnecessarily.  Constraints on environmentally injurious 
activities necessary to "production" cleanup and remediation efforts are not 
always appropriate to research, where special relief is often required and typically 
difficult or impossible to get.

The recommendation to create lead laboratories could well arise naturally, in the 
wake of other beneficial changes, but it might be well to anticipate its arrival.  The 
first task of one lead laboratory would be to organize the long-missing 
characterization of the remediation challenge mentioned earlier.  This must be 
carried out with stakeholder participation for reasons discussed above.  It would 
be a major program as it would require the participation of many of the 
Department's laboratories and EM sites .  Thoughtful options would then soon 
appear.

There are difficulties to organizing laboratory participation.  One is the need to 
insure neutrality or to have a sure mechanism for dealing with real or perceived 
drift from neutrality.  A second is the absolute need for strong leadership of the 
whole EM program.  The lead laboratory cannot provide this leadership; it must 
come from above..  Fortunately resolving the second difficulty would go a long 
way to resolving the first.




3.	The Nation



One consequence of the activities of the United States' environmental movement 
is the massive environmental cleanup underway at numerous designated cleanup 
sites as well as at many other places in the nation.  There are 60,000 EPA Superfund 
sites, 2400 Resource Conservation and Recovery Act (RCRA) sites, 22,00  state-
funded sites, and 7200 DoD sites.   The total U.S. cleanup bill is estimated to be 
about $1.7 Trillion dollars.  The program is going slowly.  "Of the $15 Billion that has 
already been spent on Superfund cleanups (across the nation), roughly 75% has 
gone to legal fees and related costs."   The need for more cost effective cleanup 
has already become an urgent matter.

Many of the problems are very similar to those that DOE faces. In particular DOD, 
EPA and others are struggling with the same technology and management issues 
as DOE.  They will badly need the technical skills that a well-organized, technically 
competent DOE effort, with national laboratory help, could provide.  For example, 
volatile organic compounds in arid and non-arid soils and ground water is one of 
the most common environmental problems in the US.  Lawrence Livermore has 
already made important contributions to the technology of dealing with them.

There is abundant evidence for the beneficial role the national laboratories could 
play in helping resolve national problems in the numerous advances that they 
have already made.  Ocean-climate interactions are being modeled by Los 
Alamos in support of Global Climatic Change studies with similar global and 
regional atmospheric modeling at Lawrence Livermore National Laboratory.  
Many of the laboratories have made contributions in the areas of environmental 
damage and resource base assessment and diagnostics.

The Department must take positive steps to encourage this attractive opportunity.  
It will, among others actions, have to consider reducing its cost-recovery fees 
levied on all  Work for Others.   These fees now signal that contributions to the tasks 
faced by other agencies of government are not a high priority with the 
Department.  The national laboratories could look forward to being available to 
the entire government system as a powerful environmental technical resource, a 
great national need.  They should become in fact, as well as in name, national 
laboratories, saving our nation significant resources and improving cleanup 
efficiency.  If the national laboratories do not fill this role, there will be no 
satisfactory alternative, and the need will remain substantially unmet.  In any event 
the experience base and the technological developments arising from the 
continuing EM program from the laboratories', industry's and research universities' 
contributions should be shared with the country on a continuing basis.

A broader vision sees the U.S. environmental and resource problems as a subset of 
many similar ones throughout the world.  Science and technology must play a key 
role in coping with them.  A strong DOE program could contribute at all levels.  We 
are the nation best equipped to contribute solutions.  Within the US, the 
Department of Energy marshals the best of these skills through its national 
laboratories and they could be put at the world's service.


F.	Concluding Remarks

The Atomic Energy Commission, and for many years the Department of Energy, 
broke the unwritten contract between these arms of government and the people 
they were to serve.  The results, contamination on an enormous scale and a bitter 
distrust, imply a deep obligation to carry through the cleanup that has now been  
launched, with efficiency, speed, and a decent respect for the opinions and 
needs of those affected.  This cannot be accomplished as things are now.  The 
changes required are clear; marshal the skills high in the DOE to bring about the 
managerial changes that are required; raise the quality of science and 
engineering in the program, among others things by utilizing adequately the great 
power available in the national laboratories as well as the power among DOE 
contractors and in the universities.  The changes only need to be set in place and 
exploited.

G.	Recommendations



	1.	Sustained improvements in DOE management and leadership are needed 
both at senior levels in the Department and in positions below the Deputy 
Assistant Secretary level.  It is clear from the above material that those 
portions of the problems that DOE can control stem from managerial 
deficiencies at the top levels in the Department.
		
	2.	A comprehensive remedy to the array of problems plaguing the EM 
program can only be achieved by a substantial commitment and high 
priority addressing the challenges of this program. These must originate high 
in the Department.  It seems clear that this must occur at the Under 
Secretary level.  This does not imply disassembling the present EM structure 
under an Assistant Secretary.  It does mean a technically adept, flexible and 
perceptive management of that and related efforts within DOE that acts 
with power.
		
	3.	Closing the science/engineering - applications disconnect should be dealt 
with by the establishment of an "Environmental Advisory Board (EAB)," 
reporting to the Under Secretary.  This should be a permanent Board and 
should include mostly scientists and engineers from within and without the 
Department and the laboratories, as well as stakeholders, to ease public 
acceptance of its recommendations.  A good review capability could be 
provided by the EAB to identify needs so as to stimulate, with Department 
support, the required basic research, development and demonstrations. 
Such  advances which should then be applied, by capable management, 
to improve field remediation activities.  The Board must have influence and 
visibility in order to fulfill its role as an instrument of the Under Secretary.  The 
High Energy Physics Advisory Panel (HEPAP) and the Nuclear Science 
Advisory Committee (NSAC) have such visibility, enhanced by their ability to 
give testimony to the Congress and their access to the Office of Science 
and Technology Policy.  They are both widely believed to be quite 
successful.  With members having a spread of skills, the Board should be able 
to provide technical oversight, flag management and regulatory 
disconnects as they arise and provide the synoptic view of the array of 
problems now lacking.
		
	4.	The national laboratories together have a critical role to play, a role very 
much larger than at present, in performing high-quality science and 
engineering for the Environmental Management program. Their principal 
contributions would be:
		


	-Help to characterize the waste remediation across the 
DOE complex as a first step in helping the Department establish 
priorities for environmental work.
 		
	-Help communicate the technical challenges to the 
appropriate research communities.
		
	-Help close the "Valley of Death," by aiding the 
construction of a seamless technology development chain.
			
The level of support necessary to implement major laboratory 
involvement as recommended here is small compared to the sums 
currently expended in the program.  As an example, an increment of 
$400 million annually for the laboratories with a ramp-up over time to 
twice that sum is roughly the scale needed to pursue research and 
development in an improved program.  In view of the large fraction 
of the nearly $7 billion annual EM budget that clearly is misspent now, 
we see no serious difficulty in redirecting funds that are already 
flowing.  No supplemental money should be required.


		
	5.	The Department must take positive steps to make the national laboratories 
available to the entire government system as a powerful environmental 
technical resource.  They should become in fact, as well as in name, 
national laboratories.  The Department must take positive steps to 
encourage this attractive opportunity.  It will, among others actions, have to 
drop, or greatly lower, its cost-recovery fees levied on  Work for Others. 
		
	6.	DOE must address more forcefully the task of renegotiating the unrealistic or 
unfeasible elements of the cleanup compliance agreements that it has 
made with State and Federal agencies.  These are now impediments from 
risk management, technical feasibility, and public perception standpoints as 
well as forcing large and fruitless expenditures.  The Federal government’s 
Superfund legislation also incorporates unrealistic goals; legislation in 1993, 
which failed to pass, addressed many of the issues which make many 
current remediation schemes impractical and expensive.  The new 
Congress, as well as DOE, should revisit the issue, benefiting DOE’s 
remediation efforts and other cleanup under Superfund.
		
	7.	Much more comprehensive involvement by members of the affected public 
in decision making should be employed to reduce the bitterness, distrust 
and distress that continues to provide a troublesome element in DOE’s 
conduct of its affairs.
		
	8.	The bulk of the EM environmental challenges, although presenting no 
immediate threats to public health or safety, still should be addressed with a 
heightened sense of urgency.  They have already been changing from 
acute to chronic problems, are becoming calcified, and the vast flow of 
funds into the program acts as an anesthetic, numbing the Department, 
State regulatory agencies and affected stakeholders, hindering and 
delaying beneficial change.





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V.The Science-Engineering Role





A.	Main Findings

The intense economic pressures now being experienced throughout the nation’s 
research and development system will likely persist for the foreseeable future.  This 
means that the nation must establish what is critical to be done and make sure 
that it is adequately funded.  It also means that institutional effectiveness, 
including cost effectiveness, must be a paramount goal of national research and 
development policies.  A prerequisite for achieving this is that there be a clear 
understanding of the relative strengths and distinct roles of the national 
laboratories, the research universities, and the industrial research laboratories so 
that an efficient division of labor can be made among them.  We will comment 
on this in the context of industrial technology development in Section VI.  Here we 
focus on DOE-sponsored fundamental research in science and engineering.

The Department of Energy is one of the principal Federal sponsors of basic 
research in the physical sciences.  The Department has the responsibility to support 
fundamental science and engineering in areas relevant to its broad missions in 
national security, energy, and environment.  Exercise of this responsibility requires a 
long-term and broad view of the areas of science that should be developed, as 
well as support for the education of the future scientific and engineering 
workforce of the United States in these fields.  Historically, the DOE and its 
predecessor agencies have provided important financial resources for science 
and engineering education.  They have also supported, as a national trust, certain 
areas of science involving the development, design and operation of large, 
complex user research facilities run for the benefit of the science community at 
large.  These scientific, technological and educational activities have contributed 
both essential human resources and technologies to DOE’s national security, 
environmental protection, and energy technology missions, and have also served 
the national interest in other domains.

DOE’s spending on basic research is heavily weighted towards its own contractor-
operated laboratories -- including those considered in this study.  These 
laboratories perform 67% of DOE-sponsored basic research, while the universities 
carry out 20%. , 


	


For the laboratories reviewed here, basic research accounts for varying fractions 
of the overall research and development effort, ranging from 56% at Brookhaven 
National Laboratory to only 0.7% at Sandia National Laboratory.  Overall, the 
laboratories devote about 19% of their combined R&D budget to basic research. 


	


Most laboratory directors believe that basic research is an essential part of their 
portfolio of activities.  We agree with their arguments that basic research is 
necessary to support their core missions, that it is necessary to attract the most 
talented people to the laboratories, and that a strong in-house community of 
experimental and theoretical researchers is necessary to keep major experimental 
facilities healthy and organic. (As a rule of thumb,  one laboratory director 
estimates that an internal community of first-rate experimentalist capable of 
successfully competing for  10-20% of the available machine time is necessary for 
this last function.)

Basic research at the DOE laboratories is under increasing pressure. In part this is 
the result of the same forces that are being brought to bear throughout the 
nation’s R&D system.  But there are several additional factors that are specific to 
the DOE laboratories:  (1) a decline in the status of basic science within DOE; (2) 
an increasing trend towards micro-management of research by DOE program 
officers; (3) the potential diversion of funds away from basic research towards the 
new technology transfer activities; (4) the decline in defense R&D funds, which 
historically have been the traditional source of support for much of the basic 
science at the weapons laboratories; (5) inadequate up-front budgetary 
allowances for operation and maintenance of large user facilities; and (6) 
increasingly burdensome compliance requirements, especially at large scientific 
facilities, which are driving up laboratory operating budgets and reducing the 
amount of funding available for research.

The Task Force is concerned about what appears to have been a significant 
decline in DOE funding for fundamental research over the past three years, with 
the prospect of still deeper cuts to follow.  The Task Force further notes that while 
these reductions have been occurring, overall support for basic research in the 
federal government as a whole has remained roughly constant or even increased 
somewhat.

The Task Force is also concerned that the distribution of DOE's basic research effort 
has failed to keep pace with recent changes in its mission.  The Department is 
aware of the problem, and has instituted steps to address it.  However, 
bureaucratic walls between program offices which contribute to the problem 
persist.  As indicated in Section IV, there is a particular need for long-term, basic 
research in disciplines related to environmental cleanup.  The activity that does 
exist in this area is poorly integrated into the cleanup program.  By focusing too 
heavily on near-term demonstrations of cleanup technology, DOE is not using its 
laboratory capabilities effectively.  The cleanup of DOE sites will not be 
accomplished in the near-term in any case, and in most situations there is no 
proximate danger to human life.  Adopting a science-based approach that 
includes supporting development of technologies and expertise in universities as 
well as the laboratories could lead both to reduced cleanup costs and smaller 
environmental impacts at existing sites and to the development of a scientific 
foundation for advances in environmental technologies (see Section IV).

Compared with the universities, the main strength of the DOE laboratories in basic 
research has generally been in building and overseeing the operation of large-
scale, complex scientific facilities (light sources, neutron sources, accelerators, 
reactors, etc.).  However, it should also be noted that not all facilities of this type 
have been located at the multiprogram laboratories, and that some, including 
some very large ones, have instead been placed at program-dedicated 
laboratories such as the Fermi National Accelerator Laboratory (FINAL), Stanford 
Linear Accelerator Center (SLAC), and the Princeton Plasma Physics Laboratory 
(PPPL).
 
The laboratories are also capable of forming large, interdisciplinary research teams 
needed for certain types of "big science" problems even where large facilities are 
not involved.  Universities are not generally as well equipped to assemble teams to 
conduct closely coordinated, multidisciplinary research over an extended period.
 
Compared with the government laboratories, the main advantages of 
conducting basic research at the universities lie in:  (1) their primary role in 
educating the next generation of scientists and engineers; (2) the rejuvenating 
effects of the constant flow of students and post-docs through university labs; (3) 
the absence of national-security-related barriers to the flow of knowledge, (4) the 
lower price charged by the universities to sponsors for comparable research in 
many cases; and (5) the quality benefits provided by the systematic application of 
the principle of merit-based competition. Merit review is applied to basic research 
at the laboratories in a variety of ways,  and sometimes unevenly.

The advantages enjoyed by the universities are most pronounced in "small 
science." However, the DOE Office of Basic Energy Sciences also supports some 
individual investigator research within the laboratories on a competitive basis.  To 
varying degrees the laboratories themselves also support such research out of their 
operating budgets.  This type of small science research at the national laboratories 
is generally of a high standard, and in some cases matches the best university 
work in the field.  On the other hand, the research culture at many of the 
laboratories has been influenced by their relative physical and intellectual isolation 
and by a sense of entitlement to research funds, and this has contributed to a loss 
of vitality in some research areas. 

The third major category of basic research institutions, corporate scientific 
research laboratories, are  being downsized, redirected towards activities with 
shorter-term commercial payoff, and in some cases dismantled altogether.  
Historically, research at these industrial laboratories has had a different character 
from either university or national laboratory research.  While long-term and often 
fundamental in nature, it has also been shaped by knowledge of markets and 
motivated by expectations of commercial opportunity.  And as two of our 
colleagues have pointed out elsewhere, "the best of the industrial laboratories 
achieved a high degree of coherence of purpose and of organizational 
cohesion, which enhanced their productivity.   And the larger enterprises could 
operate on a scale sufficient to employ experts across a broad range of relevant 
topics, facilitating work on many fronts.’ 

The nation presently faces the challenge of finding an institutional substitute for 
the corporate central research laboratories.  However, we do not think that the 
national laboratories provide a good institutional basis for a general solution.  
Partly the problem is the one discussed in more detail in Section VI.  If an 
organization is to serve as an effective laboratory for an industry, that industry must 
have a large say in allocation decisions and in evaluation. This would be awkward 
at best, and probably politically unliable, in a government-owned  laboratory.  But 
in addition, for a laboratory to perform the central research function effectively a 
considerable flow of personnel between the laboratory and the industry is 
required. University-affiliated facilities seem better adapted to meet portions of this 
need than government laboratories. In some cases, DOE laboratories may 
effectively be able to perform a function analogous to corporate central 
research.  But these are most likely to be in areas where a DOE mission -- like 
advancing superconductivity technology -- and industry interests have a strong 
overlap.


B.	Recommendations



	1.	The Department of Energy should move to strengthen its efforts in 
fundamental science and engineering, both at the laboratories and in the 
universities.   The DOE has vital stewardship responsibilities in a range of basic 
science fields, especially in some areas of the physical sciences.  Moreover, 
a strong foundation of science and engineering should underpin all of 
DOE’s programmatic missions.  The DOE should clearly define its basic 
science responsibilities, pursue them in a focused way, and ensure that 
adequate resources are available to do this.
		
	2.	The DOE should pay close attention to ensuring that a proper balance is 
maintained between the universities and the national laboratories in the 
performance of DOE-related basic research, both now and in the future. 
The laboratories are now and should remain an important part of the 
nation’s research infrastructure, providing cutting-edge scientific 
instrumentation and operating world-class research facilities. But in the 
future the Department will need to ensure that the basic research and 
associated educational programs of the universities are not jeopardized by 
an exaggerated flow of federal basic research funds to the laboratories.
		
	3.	Support for operating and maintaining large facilities in the  DOE’s Office of 
Energy Research should be  budgeted separately from funds for specific 
programs .  This will provide better accountability and budgetary control, 
and will impose greater discipline on decisions requiring trade-offs to be 
made between investing in new facilities and keeping existing ones in 
service.
		
	4.	The DOE should redouble its efforts to achieve better integration of basic 
research, technology development programs, and their applications, 
particularly in the area of environmental remediation.
		
	5.	Basic research at the laboratories should be more fully integrated into the 
national and international research community.   With the exception of 
national security-related work, all basic research at the laboratories should 
be subject to external merit review.  Barriers that currently prevent 
laboratory personnel from traveling, participating in national and 
international conferences, and spending sabbaticals in industry or the 
universities should be eliminated.  Further, to help promote the vitality of 
basic research at the laboratories, we recommend that DOE set aside small 
pools of basic research  funds in the different programmatic areas for which 
university and laboratory researchers would compete.
		
	6.	There should be additional stimulation of laboratory-university cooperation in 
basic research.  This can be achieved through measures such as having the 
laboratories support more graduate students, especially in mission-
enhancing disciplines; creating more post-doctoral positions at the 
laboratories;  arranging for university appointments for laboratory scientists 
and engineers;  and setting aside funds to be used specifically for 
collaborative research between the universities and the laboratories.  
Barriers that make it difficult for the laboratories to jointly fund research at 
universities with other funding sources should be removed.  Also, laboratory 
efforts to promote scientific education at all levels (kindergarten through 
graduate school)  will benefit from being more closely coordinated with 
parallel efforts by colleges and universities.





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	7.	





VI.The Economic Role



A.	Main Findings

The Task Force learned of significant examples of laboratory-developed 
technology being usefully transferred into industry and of the laboratories 
providing useful technical services to industry.  However, the laboratories are not 
now, nor will they become, cornucopias of relevant technology for a broad range 
of industries.  A significant fraction of the laboratories’ industrial competitiveness 
activities concern technologies which are of less than primary importance to their 
industrial collaborators and/or which these partners could obtain from other 
sources.  There are only a relatively few instances in which the laboratories have 
technology that is vital to industry and that is uniquely available at the 
laboratories.  Many firms also find it attractive to collaborate with the laboratories 
because of the availability of Federal cost-sharing funds.  In practice the 
government subsidy is often very substantial relative to the new resource 
commitments that the firms are making to these projects.

Taken as a whole, the industrial competitiveness activities at the national 
laboratories are unfocused and lack a firm policy foundation.  There is uncertainty 
within the laboratories about how large and broad-ranging these activities ought 
to be, about how to fund them, and about how they should relate to the other 
main areas of activity that the laboratories are engaged in -- in particular, whether 
industrial competitiveness should be viewed as a primary or a derivative function.  
The uncertainty within the laboratories partly reflects an inconstancy in DOE policy 
and Congressional intent regarding these issues.  One of the options that the 
Department has considered, elevating industrial competitiveness to a primary 
objective or mission, risks distorting existing programs and diverting resources 
towards activities that are unrelated to either DOE’s competencies or its other 
missions.  Such activities are unlikely to produce results that will benefit either the 
agency’s industrial partners or the public in the long run.   Recent indications are 
that DOE headquarters staff have recognized the need for greater focus in this 
area and are moving to develop criteria toward that end.  We welcome these 
developments and encourage early discussions of the evolving situation with 
laboratory leadership.

Another issue requiring clarification concerns the appropriate division of labor 
among the national laboratories, industrial research laboratories, and the research 
universities regarding industrial R&D.  The notion that the national laboratories 
should serve as a "bridge" between the research universities and industry in this 
arena -- a notion presented to the Task Force -- is not in general a useful way to 
think about this division of labor.  It does not reflect what is currently happening, it 
is not consistent with the fact of the research universities’ superior record relative to 
the laboratories as agents of technology transfer, it is difficult to reconcile with any 
plausible view of the future evolution of these institutions, and it appears to be 
based on an outdated picture of industrial innovation as a linear process that 
originates in basic research laboratories.

A more useful picture is of the laboratories serving as nodes in a  national network 
of research and development institutions, with knowledge flowing in both 
directions along the links between the laboratory, university, and firm nodes.  This 
network is simultaneously pursuing fundamental knowledge for its own sake, 
innovation for the purposes of private wealth creation, and public missions 
(national defense, public health, environmental quality, etc.), while at the same 
time educating and training the next generation of scientists and engineers.  
Because it is a true network, each type of R&D institution is involved in some way in 
all of the network’s activities, but there is specialization among them.  While the 
national laboratories are one of the primary nodes for public missions like national 
security, their role in wealth-creating innovation is necessarily secondary (and 
probably even tertiary in sectors far removed from the DOE’s mission areas).  The 
question is whether, how, and to what extent they can add value to the primary 
role of industry in this arena.




1.	The Case For Industrially-Relevant R&D At The Laboratories



There are two principal reasons why industrially-relevant R&D is seen as an 
appropriate activity for the DOE laboratories.  First, long-term research and 
development in industrial laboratories is declining, and industry is seeking 
substitutes for the functions that these laboratories once performed.  Second, 
there is a perception that the U.S. government is spending significant resources on 
the development of new technologies but that American industry is not reaping 
the rewards of that investment.  In the course of pursuing the DOE missions, the 
laboratories have developed an impressive array of core competencies, 
capabilities, and facilities, and to many it seems only logical that these resources 
be used to benefit the public in other ways.




2.	A Critical Distinction



However, what seems to have been lacking at both the DOE and laboratory levels 
is a clear understanding of the distinction between the application of laboratory-
developed technologies to industries where such application is an essential part of 
the primary mission areas of DOE (e.g., the development of energy saving 
technology for industry use, or the development of methods for analyzing and 
predicting the behavior of nuclear waste repositories, or the development of 
advanced techniques for oil field simulation) and, on the other hand, the 
application of these technologies to industries which have not had a relationship 
with DOE and whose activities lie well outside the mission domains of the agency 
and its laboratories.  Without a clear understanding of this important distinction, 
the risk is that DOE will allocate public funds and the technical and human 
resources embodied in the laboratories in unfruitful ways.

To clarify and sharpen this distinction, we have found it useful to categorize  the 
range of possible laboratory activities in industrially-relevant R&D according to 
their position in the simple matrix shown in Figure 2.  In practice the boundaries 
between the classes of activity shown in Figure 2 are imprecise, but the basic 
distinctions are important nonetheless.  The four categories are as follows:
 




	
	-Near-term R&D applied to industries outside traditional DOE mission areas 
(i.e., national security, energy, environmental remediation).  To be effective, 
near-term R&D work must take place in an environment rich in interactions 
with users and customers.  Market-based influence, direction, and control 
are critical to success.  In recognition of this, firms themselves have been 
evolving towards a more integrated process for developing new 
technologies, in which all participating Departments and disciplines are 
drawn into close and continuing interaction with the marketplace. The more 
distant the laboratories are from the marketplace, the more remote the 
likelihood that they will have something useful to contribute to such 
activities.  Near-term development work at the laboratories is least likely to 
provide substantial contributions to industries outside of DOE’s traditional 
domains of national security, energy, and certain aspects of the 
environment.
		
	-Longer-term R&D applied to industries outside traditional DOE mission 
areas.  The potential contribution of longer-term laboratory research and 
development to commercial applications outside the DOE mission areas 
should similarly not be exaggerated.  While there are instances of successful 
"by-product" R&D, the historical evidence demonstrates that such events are 
statistically improbable.  Even for longer-term development activity, strong 
interactions with the marketplace are usually essential to success.  To 
provide industry benefits, such long-term R&D would need to be tied closely 
to groups of industries that have never had close association with the 
laboratories, their people, or their culture, an unlikely prospect for creating 
useful results.  Moreover, to be useful in a different industrial context, 
substantial technological modifications are almost always necessary, so if 
the laboratories are engaged in such activity resources will inevitably be 
diverted from their primary missions.
		
	-Longer-term R&D applied within traditional DOE mission domains.  For 
firms and industries that are contributing to DOE’s traditional mission 
objectives, the national laboratories have a useful role in carrying out long-
term research and development with potential commercial applications.  
Indeed, it is even possible to imagine the laboratories playing a role with 
respect to these industries comparable to that which used to be played by 
central corporate research laboratories.  Here the alignment between DOE 
and industry objectives is much closer by definition, and both DOE and its 
laboratories have more knowledge of their industrial partners’ market 
environment.  Longer-term research and development of this kind 
undertaken by the laboratories does not require day-to-day direction by 
industry, but close interactions are still important.
		
	-Near-term development applied to traditional DOE mission domains.  
Firms and industries that are participating with DOE in pursuit of its traditional 
missions of national security/energy/environmental pollution control and 
remediation  may become aware of technical developments at the 
laboratories that will help them in solving a short-term product or process 
development problem.  In such cases industry should be an active partner in 
directing the course of development, and should be encouraged to transfer 
interim laboratory outcomes into its own internal industrial R&D programs 
through the appropriate licensing mechanisms.






3.	Expansion Outside DOE Mission Areas



We are concerned about the implications of expanding the laboratories’ industrial 
R&D activities outside the existing DOE mission areas.  If the DOE is to get into 
programs whose primary mission is to meet a need of private industry (as 
contrasted with programs where private industry needs are complementary to 
government needs, but not dominant), private industry will need to have a large 
say in allocation decisions and in evaluation, since only industry has the intimate 
knowledge of the marketplace that is critical to the success of such efforts. The 
difficulty comes in reconciling this need for industry direction with the parallel need 
for public influence over the disposition of public resources at government 
laboratories.

We are also concerned that the expansion of the laboratories’ roles in serving the 
technology needs of private enterprise will create additional managerial problems 
within DOE.  For any organization to be effective, the activities it manages need to 
be associated with a coherent set of objectives.  Otherwise, it is virtually impossible 
to allocate resources rationally, or to evaluate the various activities and programs 
in terms of how they contribute to the performance of the organization as a 
whole.  This is amply borne out by experience in private enterprise which indicates 
that most conglomerates do badly, especially in managing technological 
innovation.  Under statute, the DOE is faced with the considerable challenge of 
managing an already diverse set of missions.  Adding to this complex task the 
requirement to consider the technology needs of the private sector in areas not 
related to the Department’s traditional domain of activity is likely to distract DOE 
from its public missions and lessen its impact while undermining the effective 
pursuit of those industrial objectives. We are concerned that "porkbarrel" criteria for 
program funding might increasingly replace more rational resource allocation, 
and that the laboratories might be more likely to propose industrial programs 
merely based on "make work" criteria.

We are further concerned about the possibility that DOE and its laboratories, in 
engaging in industrial R&D, may find themselves competing with private firms in 
providing technical services or new technological developments.  In such a 
situation, the laboratories’ access to public funds would give them an 
inappropriate advantage.  Such situations are more likely to arise the less DOE and 
laboratory management know about the commercial application in question.  We 
are already aware of some instances in which such competition appears to have 
occurred, and we are concerned that the problem may become more serious in 
the future.

All of these problems can be ameliorated if the industrially-related R&D done by 
the laboratories is focused on industries and applications which are themselves 
instrumental to  achieving the DOE’s public missions. That is not to suggest that 
laboratory directors should be denied the flexibility to initiate new technical 
projects at the periphery of current activities.  Making room for individual and small 
group initiatives of this kind is an important way to keep the laboratories lively and 
exciting places to work.  If such a project becomes large enough, though, a 
judgment must be made as to its fit with the rest of the laboratory’s activities.  This 
will depend not only on technical compatibility but also on the project’s 
relevance to the laboratory’s (and hence the DOE’s) missions.

The current industrial partnership activities of the laboratories have brought them 
into contact with a number of industries that do not lie within the Department of 
Energy’s traditional domain.   In addition to the drawbacks specified above, these 
new involvements also suffer from a number of other problems:



	-They are unfocused.  Without a connection to the Department’s larger 
public missions, these initiatives are invariably add-on activities, managed 
on a case-by-case basis, through a well-intentioned but necessarily ad hoc 
relation to industry.  The laboratories should not aspire to become research 
boutiques for industries.
		
	-Their short-term benefits are often oversold.  Even when useful results 
flow from these partnerships, the benefits to the participating firms generally 
will not be evident for some time, and are inherently difficult to measure.
		
	-They distract the DOE and its laboratories from their public missions, 
diverting both intellectual and material resources.






4.	Technology Partnership Mechanisms



Cooperative Research and Development Agreements (CRADAs) currently occupy 
pride of place among the array of mechanisms employed by DOE to encourage 
laboratory-industry cooperation in technology development and transfer.  
Introduced to the laboratories in 1989,  the CRADA mechanism reflects the intent 
of Congress, developed and refined in legislation over the preceding decade, to 
ensure a greater degree of laboratory involvement in industrially relevant 
activities.  Industry criticism of the CRADA mechanism has focused on the slow and 
uncertain nature of the negotiation process.  The DOE and the laboratories have 
responded to these concerns.  Nevertheless, there remain wide variations across 
the laboratory system in the speed with which CRADA negotiations are being 
concluded.   Ironically, recent contractual reforms intended to encourage more 
businesslike relations between DOE and its management and operations (M&O) 
contractors at the laboratories risk complicating laboratory/industry negotiations 
because the contractors are more strongly motivated than before to secure rights 
and to take direct profits from laboratory-generated intellectual property.  The 
Task Force believes that the contract-driven M&O motivation to profit from 
laboratory intellectual property will act as a significant barrier to industry 
acquisition and subsequent commercialization of laboratory technology in the 
future.

Other criticisms focus on the lack of independent review of the  operation and 
outcomes of CRADAs , and also the process used to select industrial partners for 
these agreements.  Regarding the latter, when a CRADA proposal is submitted 
there is typically no solicitation of competing proposals, nor an announcement 
that public resources are available for such work and will be awarded exclusively 
to the applicant company if others do not step forward. Nor is the peer review 
process as rigorous as other DOE programs; independent expert evaluations of the 
validity of the proposed work and its relevance to the DOE mission are not 
routinely solicited. These practices can be traced to earlier legislative and 
executive branch attempts to reorient the laboratories towards industrially relevant 
activities as rapidly as possible.  However, their practical effect today is to leave 
the laboratories vulnerable to charges that the selection process is flawed and 
that the competitive playing field is being unfairly tilted towards the laboratories’ 
chosen partners.  In fact, DOE routinely and successfully implements several 
different models of independent peer review, at least two of which are relevant to 
the present situation -- the allocation of DOE beam line resources, and the 
allocation of funds under the Small Business Innovation Research (SBIR) program.  
The DOE should consider applying these practices to CRADAs as well.




5.	Metrics



One of the most common metrics used by DOE and others to assess the 
technology transfer performance of the laboratories is the rate at which new 
CRADAs are being signed.  An obvious limitation of this metric is that it measures 
inputs rather than outcomes, and the latter are likely to vary greatly from one 
CRADA to another. It also fails to distinguish among different classes of CRADAs.  
Some pertain to work that the laboratories would have undertaken anyway, even 
if no CRADA had been signed. Others entail a significant departure from a 
previous program of work.  In some cases technology transfer activities have 
reportedly drawn the laboratories away from their primary missions.  In others, 
resources appear to have been diverted away from fundamental research to 
support them.  In such cases, a cost-benefit metric may be the only meaningful 
measure of performance.  We also note that none of the laboratories appears to 
be measuring the effectiveness with which technology is being transferred in from 
industry or the universities to support their missions.  In general, we recommend 
that greater emphasis be placed on outcomes in the measurement of  
technology transfer performance.  The question of performance metrics for the 
laboratories in discussed further in Section VII of this report.


B.	Recommendations



	1.	The government-funded technology transfer/industrial competitiveness 
activities of the national laboratories should be focused on industries and 
areas of technology that contribute directly to the DOE’s primary missions in 
national security, energy and environment.  Industrial competitiveness, 
broadly defined, has no place as a stand-alone mission of the laboratories, 
but rather should be regarded, and treated, as a derivative of their primary 
missions.  The idea that the laboratories are, or could become, cornucopias 
of relevant technology for a broad range of industries is a myth.
		
	 2.	Laboratory directors should have the flexibility to initiate or to  approve new 
technical projects at the periphery of current laboratory activities.  But if 
these initiatives are unrelated or only tangentially related to the public 
missions of the DOE, either different sponsors should be found or the work 
should be spun off into the private sector once the level of activity exceeds 
what can reasonably be funded out of the laboratory director’s limited 
discretionary account.
		
	3.	Competitive selection and more rigorous technical and merit review by 
external experts should be applied broadly within the Department’s CRADA 
activities.  There are several alternative models available to DOE for this 
purpose, including programs currently administered by the DOE itself.  One 
strategy would be for DOE to link some portion of its SBIR programs to 
CRADA activities.  The two programs have similar legislated 
commercialization objectives, which should make them compatible.  In 
addition, making this linkage would help to achieve a higher 
commercialization rate by maximizing the available resources (both cash 
and in-kind R&D).  Improvements in the CRADA selection and monitoring 
process need not, and should not, incur any penalty in the timeliness of the 
process.  The DOE should continue to focus on reducing the time required to 
complete CRADA negotiations and on bringing the laboratory system as a 
whole up to the standard of best practice established by the leading 
laboratories.





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4.





VII.The Governance and Organization Issue



A.	Introduction

In accepting its privileged assignment of suggesting alternate futures for ten 
Department of Energy laboratories, this Task Force could have limited itself to the 
conventional objective of most Federal advisory studies and only presented 
findings and proposals that might be adopted within the accepted governing 
processes of the times.  But one critical finding is so much more fundamental than 
we anticipated that we could not in good conscience ignore it.  The principle 
behind that finding is:  Government ownership and operation of these laboratories 
does not work well.

The laboratories are purported to be contractor operated.  The system is titled 
Government-Owned, Contractor-Operated or GOCO.  The GOCO system was a 
promising concept.  The Contractors, as contractors, do yeoman work.  The system 
has been employed for decades.  But in that time it has followed the natural 
course of government's proclivity to govern more.  The owner wants to take 
charge more.  Most able government personnel aspire to add value.  Translation:  
add more governance.  This makes work for more government personnel, 
increasing the size of the operation, increasing still further need for management, 
ad infinitum.  Congressional policy has significantly driven this consequence.

Numerous instances of poor DOE regulatory and management practices have 
come to the attention of all members of the Task Force during its investigation of 
the national laboratories.  The system has been tried long enough; the evidence is 
in.  Today, the system has evolved to a virtual GOGO - Government-Owned, 
Government-Operated, but certainly strongly government-dominated system.  
And the momentum in that direction has been unabating.  This  ship of state  (the 
Congress/Department/Contractor/Laboratory system) is ponderous.  Evidence in 
these regards is almost limitless.  Appendix A illustrates the excessive oversight and 
micromanaging with an abbreviated litany of some forty anecdotes.  However, 
general areas of excess are:


		


	-Growing emphasis on DOE administration and support organizations and 
their oversight and compliance roles;
		
	-Expanded DOE field office management oversight roles, which are 
commonly duplicative of other management channels;
		
	-Increased audit oversight and too many review groups, both internal and 
external.  The increasing costs of dealing with review groups, both in 
resources and in their consumption both of senior and junior staff time, leads 
to paralysis and interferes with operations; and
		
	-One array of difficulties with which DOE has not yet been able to deal 
properly is ironically self-inflicted.  Far too much influence has been ceded to 
non-regulatory advisory boards, such as the Defense Nuclear Facilities Safety 
Board.  Such organizations generate recommendations with no apparent 
cost / benefit analysis, resulting in significant unnecessary expenditures and 
productivity losses.



 As we were in the final stage of editing our report and preparing for submission, 
the Department initiated a Strategic Alignment effort to address some of these 
issues.  The initiative is described in the announcement and explanation 
documents of the Department which were released on December 20, 1994.  The 
Task Force applauds the Department's acknowledgment of the problem and 
many of its intended actions.  The Task Force presumes no credit for this 
happening.  Rather, we note that the establishment of this Task Force was itself an 
initiative of the Department a year earlier.  The natural consequence was to put 
the governance issue into public play, and the Department has been responsive 
to the inevitable greater emphasis of this governance issue to its credit.

There is heartening evidence from inside the Washington Beltway regarding the 
suffocating consequences of micromanaging.  It confirms our finding that 
something really substantial has to be done soon or the vitality of the laboratories 
will founder.  But our evaluation of the seriousness of the problem and the limited 
promise of a continuing federal governance system even though partially muted, 
per the new Department proposals, is that efforts such as announced will be 
seriously insufficient.

It is the Task Force's position that top-down, command and control bureaucracies 
are counterproductive for these laboratories.  Pundits may dismiss this reality.  But if 
the laboratories are to optimally enhance America's energy interests, these are 
the realities of group dynamics essential for the laboratories to contribute their 
best.

Thus, our first operations recommendation is that we must begin to evolve, over a 
period of one or two years, the development and implementation of a new 
modus operandi of Federal support, based on a private sector style  corporatized  
laboratory organization system.  This proposal embraces the counterintuitive, yet 
newly-further-confirmed institutional principles that allow the subsets of an 
organization to operate more to the principles of trust and self initiative.  From 
these principles accrue greater flexibility, quality, and productivity; as well as the 
revitalization of an operating institution and the heightened accomplishment of its 
mission.

There have been many studies of the Department of Energy laboratories.  As one 
reads these reports, one recognizes that the items which were recommended in 
previous reports are for the most part recommended in most subsequent reports.  
As each past study has taken place, people of good intention do make sincere 
efforts to  fine tune  the system.  However, the Department and the Congress 
should recognize that there has been little fundamental improvement as a 
function of past studies.  In fact, the cost-benefit relationship of the 
Department/Laboratory operation has continued to degrade.  If there is to be a 
significant benefit from this study, it will have to come as a function of a major 
organization and governance change.

We suggest that the country must try one or more concepts that are radically new 
in order to revitalize the laboratories and to achieve significant improvements.  If 
some parts of a bold solution  were to prove to be not as beneficial as this Task 
Force is confident that they would be, that unto itself should not be a matter of 
concern.  The laboratories and the country would still be better off than they 
otherwise will be from the continual repetition of federal governing policies.  The 
system is now so concerned with details that it cannot work the big picture.

Previous reviews of the laboratories have taken a top down approach.  This one 
focused otherwise.  Early on we invited the involvement of the people active in 
the system from the bottom up.  It is evident to us that the competence is there in 
the laboratories to make these changes.  Properly oriented and supported with 
quality management training, this inherent competence can make enormous 
changes in the productivity and effectiveness of the laboratories.


B.	The Need to De-Federalize

The principal organizational recommendation of this Task Force is that the 
laboratories be as close to corporatized as is imaginable.  We are convinced that 
simply fine tuning a policy or a mission, a project, or certain administrative 
functions will produce minimal benefits at best.

The government should be the customer of the laboratories.  The Department itself 
should be an instrument of that customer function.  The Department must become 
a world-class customer.  World-class commercial customers do not tell their 
suppliers how to do things.  They simply buy a result for a given price.  World-class 
commercial suppliers are not audited by their customers.  The commercial 
practice sets the quality of operations standards to which the government should 
commit.

The Task Force is aware that there are numerous laws on the books that specify 
that things should be done the way they are currently being done.  The Task Force 
recommends that a clean sheet of paper be applied to the design of a new 
laboratory governance system by the Congress and the Department.  The Task 
Force notes that over the years creative variations of government structures and 
funding have been flexibly initiated, including the Defense Advanced Research 
Projects Agency (DARPA, now ARPA) the Federal National Mortgage Corporation, 
Mitre Corporation, and many others.  This precedent justifies the application of 
imaginative and practical forms and financing of organizations such as we 
propose, including the circumscribing of prescriptives, audits, and other overhead.

One attractive model that we outline here is the creation of a new not-for-profit 
R&D corporation or corporations, formed with many of the basic principles and 
criteria of a conventional commercial corporation.  Although the DOE weapons-
oriented laboratories could be omitted from the proposal outlined here, many if 
not all of the other DOE national laboratories at least are candidates to be 
included in this corporation.  The not-for-profit corporation(s) will be governed by a 
Board of Trustees, consisting primarily of distinguished scientists and engineers and 
experienced senior executives from U.S. industry, appointed to staggered terms by 
the President of the United States.  This Board will select the chief executive officer 
and other principal officers of the corporation.   Each lab would similarly have a 
trustee advisory board elected by the parent board.

The Department of Energy will be the government sponsor of this new R&D entity.  
Initial funding of the corporation will be in the form of Congressional line items in 
the DOE budget in each of the four mission areas of national defense (if the 
weapons laboratories are included in the  corporation ), energy, basic research 
and environment; and another line item for  other programs,  a miscellaneous 
category including health, facility improvement, global ecology, economic 
betterment, etc.  Each of those missions will contain funding that can be used 
across the full R&D spectrum from basic research to development and technology 
demonstration.  The budget should be for some multiple of years with our Task 
Force recommending that a decline be built into these funds over a five year 
period.  Renewal of federal funding will be subject to Congressional approval.

Allocation of these funds among its several individual laboratories will be made by 
the corporation.  The management of the corporation will deal with the traditional 
agencies for which the work is usually done in refining the allocations.  
Micromanaging or  earmarking  of these allocations should not be made by the 
Congress or the Department.

The corporation will be permitted to serve the particular needs of the Department 
of Defense, the Department of Energy, as well as any others in government, the 
universities and the private sector, just as any corporation would serve its 
customers.  The corporation will be subject to normal commercial criteria of 
operation, including conventional outside auditors, as are required of other 
corporations.  The corporation and its several laboratories will be subject to the 
normal influence and control of those agencies of the state and federal 
government that normally have authority over a United States corporation.  If it 
wishes, the corporation may hire one or more contractors, similar to those now 
engaged by the DOE, to assist it with aspects of the management of its affairs.

The laboratories will be challenged to embrace the new higher standards of
self initiated, self determined, quality service to customers that are being 
perfected in the private sector.  As a result, the Department will receive more  
bang for the buck .  There is a spectrum of possibilities from which a new system of 
governance and operation can design the needed better way.  Although we 
have outlined one specific embodiment of a corporate structure, many variations 
are possible.  As mentioned above, the weapons- laboratories may or may not be 
included in such a  corporatizing,  although some Task Force members feel 
including them would be both useful and successful.  Various options also exist for 
ownership of the plants and facilities.  For example, they may be leased to the 
corporation on a long-term or rolling basis, or they may be transferred outright.  
Combinations of operating plans can be staged in transition to a  far-less-federal  
plan as a further possibility.

In this model, the DOE is the customer of the corporation.  Funding  for the 
corporation would be allocated to the DOE by Congress in a small number of 
broad blocks as described earlier.  Allocation to specific projects would be the 
responsibility of the DOE, with no earmarking from Congress beyond quantifying 
the amount of money given to each broad block.  Congress would indicate its 
level of satisfaction with the job the DOE was performing by increasing or 
decreasing the funding to each broad block.  The DOE, in turn, would indicate its 
satisfaction with the job the corporation and its parts are performing by increasing 
or decreasing the level of funding for each project.

The contemporary official view is that the laboratories must conform to the so-
called federal norm.  The Task Force believes it is time to run a major experiment 
with a modest part of the federal budget and have the laboratories test out a 
progressive concept.  The current annual budget of some $6 billion for these 
laboratories is modest compared to the entire government budget, or even the 
budget of many large corporations.  At minimal risk, the country could experiment 
with a new way of doing things.  It is just such quality of change that is renewing 
the rest of America to heightened achievements and increased competitiveness 
with resultant ability to achieve improved results with a smaller budget.

A compelling question is: what are the cost savings consequences of the change 
in governance and reorganization?  Each time we tested the question on the 
players-those who work in the laboratories-the least called out was  10% savings ; 
to which most all other respondents would strenuously interject  40%,   25%,   50%,   
20%.   In private industry it is virtually axiomatic that a dedicated, empowered, 
quality program will generate better than 20% cost improvements with greater 
values in significantly improved quality of output of services, engineering and 
product.

As described in its Strategic Plan, the Department of Energy sincerely desires to be 
people oriented, to value creativity and innovation, to commit to excellence, to 
work in teams, to embrace leadership empowerment, and to pursue 
accountability.  Regrettably, the fundamental system and structure under which it 
is obliged to operate cannot achieve the first five objectives to near the degree 
the Department leadership intends.  The Department further recognizes that 
certain critical success factors are communications, trust, and human resources.  
Again, its hands are tied as it is obliged or elects to overadminister.  The activities 
that it is obliged to direct and order are a countervention of the value of trust.  The 
laboratory human resources are demotivated by such an environment.

The above are our recommendations of the type of substantial reorganization 
which could be expected to result in an improvement of between 20 and 50 
percent in the effectiveness of the laboratories themselves, on top of significant 
staff and overhead economies in the Department.  For example, under the 
proposed structure the present DOE Field Offices might have no role to play vis-a-
vis the laboratories.

In implementing the proposed corporatization, a separate detailed  identification 
of those services which only the government can provide as a supplier should be 
identified.  One example may be the transportation of nuclear or other dangerous 
materials.  These services could be purchased by the laboratories from the 
government.

Certain of the liability responsibilities that have been placed on the government's 
shoulders must be continued (at least relating to past government assignments, 
such as nuclear materials) absent bad faith and willful misconduct on the part of 
the laboratory corporations.

C.	Other Subjects




1.	Financial Resource Planning



The laboratories must have a reasonable predictability as to their financial 
resources.  In this way, the people who work at the lab will be more secure in their 
professional futures, and will be further motivated to become the supremely 
productive entity to which they aspire.  Some form of multiple year fund 
guarantees are essential.  We must find a way under the  clean sheet of paper  
doctrine of making this possible.  We must further be willing to find ways of 
engaging cooperatively with foreign sources of funds for research and 
development, as such cooperative work will often multiply the effectiveness of the 
domestic work to our benefit.




2.	The Laboratories As a System



One of the values of this Task Force process has caused the laboratories to come 
together as a system to a greater degree than they had been inclined or directed 
to do in the past.  The laboratories could move to a virtual system, such as is 
described elsewhere in the report.  This would be more readily accomplishable 
under Corporate structuring.




3.	Technology Roadmaps 


The Task Force suggests that there be a more liberal application of the technique 
of defining technology roadmaps for those classes of technology which would 
yield to a roadmap.  We urge that this management process be employed where 
practical.  All appropriate constituencies from government, academia, industry 
and the laboratories who have a competence at contributing to a given 
roadmap, should be called upon to define such roadmaps in a manner similar to 
that which has been accomplished by the semiconductor industry.




4.	The Globality Issue (vis-a-vis non-Defense technology)



These laboratory Corporations will be serving other private corporations.  They 
must not be unduly inhibited by policies that restrict the use of the technology to 
American sites or to American personnel.  This is a global energy economy and 
general economy.  All users of knowledge must be able to use the knowledge, 
wherever that knowledge can best serve their customers.  If that requires doing 
some further engineering or production overseas, such investments will do nothing 
but enhance the economic strength of America through exports and the lowering 
of trade barriers, with the eventual desired job creation at home.  Some further 
liberalizing of the  design and manufacture only in America  must be effected.




5.	Metrics


 
At the onset of the Task Force study, a request was made to identify metrics of the 
laboratories' work.  In no order of importance these can include:  adherence to 
budgets, adherence to project schedules, patents filed, inventions disclosed, 
estimates of cost savings from a given potential application or actual application 
of technology, lists of technical problems solved, research dead ends now 
avoidable, the quantity and quality of research papers published, lab/university 
and lab/industry interactions as well as other collaborative work anecdotes, 
including CRADA results.  The presently overused metric of  jobs expected to be 
produced from a CRADA  should be discouraged as speculative at best.

The degree to which a laboratory engages in the process of renewal would be a 
significant measurement.  Science change, laboratories change, and laboratories' 
missions change.  Laboratories such as Lawrence Livermore, for example, have 
changed over the last forty years having naturally gone from an 90 percent 
national security orientation to a 60 percent other class of activities orientation.  
Major projects like the Bevatron at Lawrence Berkeley Laboratory, which played 
an early important role, have been closed.

It is worth having metrics on how well the government is performing to make 
possible the better work of the laboratory and to expedite the application of 
certain of the output of the laboratories.  For example, to what degree is the 
government becoming a better customer of the development, to what degree is 
it moderating regulations, to what degree is it making aid available tied to the 
development to encourage the commercial exploitation, to what degree is it 
making available low cost capital, what are the practical honorable ways of 
reducing the risks that would be borne by investors, how is the network of 
extensive testing facilities used to enhance and advance the application of 
products, how willing is the government to identify with the beginning success of a 
technology roadmap to support more vigorously extensions of achievements on 
that roadmap.

When all is said and done, the nature of the laboratories as a multidisciplinary 
system providing solutions to some of the truly challenging puzzle of nature, will 
require a qualitative evaluation more than anything else and a long time horizon 
to best measure the results.




6.	Quality



The Department of Energy and most of the laboratories have embraced the 
language of quality management. They have studied the issue, they articulate the 
principles and they are educated on the fundamentals.  The pursuit of these 
quality initiatives and the embracing of the practical methods and procedures of 
quality should produce values for the Department and the laboratories.

However, the likely end result will be limited because the principal authorities do 
not adequately appreciate a major way one improves quality:  the elimination of 
functions.  One must simplify procedures and get down to their essences, and the 
people in government are not prone to this.  They administer quality in, control 
quality in, and audit quality in.  Exactly the opposite is  obliged.  One cannot have 
a quality effect through the manner in which government imposes itself on the 
operations of the laboratory.  We call for a true quality program.  It must start at 
the top.  It must start with the Congress and the Administration.  When it starts 
there with proper respect for the essential principles, the ultimate result will require 
the government to  get out of the way  so that the laboratories can practice the 
quality principles that are practiced in the private sector.

Consider this excerpt from an article,  Why to go for Stretch Targets,  in Fortune 
Magazine:   Finally_--_ and here's where stretch targets differ from old-fashioned 
top-down management by fiat that U.S. companies have spent years unlearning_-
-_ the CEO has to get out of the way.  The job belongs to managers in the field, 
workers on the plant floor, and engineers in the labs.   




7.	Facilities



There are superb facilities at the government laboratories.  There are also facilities 
that have been allowed to languish.  The insufficient attentiveness of the 
Department in keeping up the quality of existing facilities or the disposition of 
obsolete facilities is evident.
There should be a gradual reinvestment by the federal government in repairing 
research laboratories, and upgrading research instrumentation.  Once that has 
been achieved after a period of years, the responsibility should be turned over to 
the laboratories.  The laboratories should be expected to maintain and renew 
facilities in the same manner that the private sector is obliged to perform the 
updating, the tearing down and the construction of new facilities from their then 
aggregate budget assignments.

Elements of such a facility renewal plan should include:



	-Facility consolidation, including decontamination, decommissioning 
and disposal of all non-essential structures and equipment.
		
	-Upgrading all essential facilities to meet modern safety facilities.
		
	-Initiate an enhanced maintenance program for all nuclear facilities 
bringing ongoing maintenance to appropriate industrial standards.
		
	-Complete and maintain all safety related documentation.
		
	-The laboratories should see to the training of the work force to 
successfully implement and maintain safety and environment systems 
regarding such facility.



If we do not correct this facility situation, the cost of managing and maintaining 
facilities  today's way  will soon be so costly that it may substantially consume the 
laboratories' budget.  If the full management responsibilities of the facilities are 
placed in the hands of the management of operations (that is, the laboratory 
directors responsible to their public trustees), we anticipate that  the cost of facility 
maintenance will be significantly improved.


D.	Recommendation



	1.	Over a period of one to two years, the Department and Congress should 
develop and implement a new modus operandi of Federal support for the national 
laboratories, based on a private sector style -  corporatized  - laboratory system.





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	2.	





VIII.Summary of Recommendations



For detailed versions of the following recommendations please refer to the body 
of the text.

A.	National Security

1.	The primary mission of the weapons laboratories must be a safe, secure and 
reliable nuclear stockpile in the absence of explosive testing.  Science-based 
stockpile stewardship is the approach chosen be the Department to achieve this 
mission.  It requires the following rank-order priorities:
	


-	Attracting and retaining skilled scientists, engineers, and managers over the 
years ahead with the expertise required for the complex and changing 
stewardship role;
	
-	Enhancing surveillance of weapons in the stock pile, during dismantlement, 
and of the nuclear materials that accumulate as a result of the dismantlement;
	
-	Continuing hydrodynamic testing to cope with problems;
	
-	Assessing problems, reanalyzing previous data through numerical 
simulations, and developing appropriate data bases; and
	
-	Sustaining the scientific process of inquiry through experimentation.


	
2.	Non-proliferation, counter-proliferation, verification, and intelligence support 
have become a major mission along with stewardship of the nuclear stockpile.  
The Task Force notes that organizational compartmentalization within the 
Department complicates and makes difficult the appropriate inter-relationship 
and funding balance between support and non-proliferation, and recommends 
that the Department's organization reflect their importance and 
interdependence.
	
3.	The Task Force believes Lawrence Livermore National Laboratory should retain 
enough nuclear weapons design competence and technology base to continue 
its activities in non-proliferation, counter-proliferation, verification, an intelligence 
support, to provide independent review for several years while alternative 
approaches to peer review are developed, and to participate in weapons 
relevant experiments on the National Ignition Facility (NIF).  Lawrence Livermore 
National Laboratory would transfer as cost-efficiency allows over the next five 
years its activities in nuclear materials development and production to the other 
design laboratory.  Lawrence Livermore National Laboratory would transfer direct 
stockpile support to the other weapons laboratories as the requirements of 
science-based stockpile stewardship, support of the DoD nuclear posture, and the 
status of the test bans allow.
	
4.	The Task Force recommends continued funding support for the Dual-Axis 
Radiographic Hydrodynamic Testing (DARHT) facility; continued near-term support 
for the Los Alamos Neutron  Scattering Experiment/Los Alamos Meson Physics 
Facility (LANSCE/LAMPF); continued pursuit of advanced computing, including 
computing through workstation networks; and proceeding with the National 
Ignition Facility (NIF) as a research facility, balanced with respect to other major 
investments.
	
5.	The Task Force recommends that future production needs should be based 
on residual capabilities of Pantex, Los Alamos National Laboratory, and Sandia 
National Laboratories, and believes that no further investments in production 
capability are needed at this time.


		



B.	Energy, Environment, and Related Sciences and Engineering Role



1.	The Department should organize itself to achieve greater integration among its 
applied energy programs, between these programs and industry, and between 
the applied energy and basic energy research work performed at the 
laboratories.
		
2.	The integration of energy and environmental considerations should be a 
fundamental organizing principle for much of the Department's activities.
		
3.	The Department and the national laboratories should move promptly to establish 
clear mission statements for the laboratories which will be utilized as tools for 
budget decisions and long-term strategic planning.
		
4.	Mechanisms should be established to enhance the management of the multi-
program laboratories as a system.
		
5.	The Department should establish lead laboratories according to mission 
assignments and programmatic strengths.
		
6.	The Department should establish Centers of Excellence within the laboratory 
system.
		



C.	Cleanup of Radioactive and Chemical Wastes



1.	Sustained improvements in DOE management and leadership are needed both at 
senior levels in the Department and in positions below the Deputy Assistant 
Secretary level.
		
2.	A comprehensive remedy to the array of problems plaguing the EM program can 
only be achieved by a substantial commitment and high priority addressing the 
challenges of this program.
		
3.	Closing the science/engineering - applications disconnect should be dealt with by 
the establishment of an "Environmental Advisory Board (EAB)," reporting to the 
Under Secretary.
		
4.	The national laboratories together have a critical role to play, a role very much 
larger than at present, in performing high-quality science and engineering for the 
Environmental Management program.
		
5.	The Department must take positive steps to make the national  laboratories 
available to the entire government system as a powerful environmental technical 
resource.
		
6.	DOE must address more forcefully the task of renegotiating the unrealistic or 
unfeasible elements of the cleanup compliance agreements that it has made 
with State and Federal agencies.
		
7.	Much more comprehensive involvement by members of the affected public in 
decision making should be employed to reduce the bitterness, distrust and distress 
that continues to provide a troublesome element in DOE’s conduct of its affairs.
		
8.	The bulk of the EM environmental challenges, although presenting no immediate 
threats to public health or safety, still should be addressed with a heightened 
sense of urgency.




D.	Science-Engineering



1.	The Department of Energy should move to strengthen its efforts in fundamental 
science and engineering, both at the laboratories and in the universities.
		
2.	The DOE should pay close attention to ensuring that a proper balance is 
maintained between the universities and the national laboratories in the 
performance of DOE-related basic research, both now and in the future.
		
3.	Support for operating and maintaining large facilities in the  DOE’s Office of 
Energy Research should be  budgeted separately from funds for specific 
programs.
		
4.	The DOE should redouble its efforts to achieve better integration of basic research, 
technology development programs, and their applications, particularly in the area 
of environmental remediation.
		
5.	Basic research at the laboratories should be more fully integrated into the national 
and international research community.
		
6.	There should be additional stimulation of laboratory-university cooperation in basic 
research.




E.	Economic



1.	The government-funded technology transfer/industrial competitiveness activities 
of the national laboratories should be focused on industries and areas of 
technology that contribute directly to the DOE’s primary missions in national 
security, energy and environment.
		
2.	Laboratory directors should have the flexibility to initiate or to  approve new 
technical projects at the periphery of current laboratory activities.
		
3.	Competitive selection and more rigorous technical and merit review by external 
experts should be applied broadly within the Department’s CRADA activities.



 
F.	Governance



1.	Over a period of one to two years, the Department and Congress should develop 
and implement a new modus operandi of Federal support for the national 
laboratories, based on a private sector style -  corporatized  - laboratory system.






Appendices





Appendix A: Excessive Oversight And Micromanaging





The present structuring and operation of the laboratories is governed by the class 
of contracting:  Government-Owned, Contractor-Operated (GOCO).

Were it possible to have a true government-owned, contractor-perated system it is 
conceivable that there could be a continuing activity under such a rubric.  But 
wherever we turn we see evidence of nothing but a government owned and 
more government operated system. 

As a function of the detail with which the Congress prescribes what should be 
done in the laboratories and the Congress's obsession with the issue of 
accountability, the Department is driven both to honor the prescriptions from 
Congress and to overprescribe in order not to be at risk of failing to be super 
attentive to the Congress's intentions. 

The net effect is that thousands of people are engaged on the government 
payroll to oversee and prescribe tens of thousands of how-to functions.  The 
laboratories must staff up or reallocate the resources of its people to be responsive 
to such myriads of directives; more and more of the science intended resources 
are having to be redirected to the phenomenon of accountability versus 
producing science and technology benefits. 

This report could contain thousands of supportive pages from the thousands of 
involved people who unanimously complain of this phenomenon.  We will merely 
illustrate with a few examples that could be multiplied were we to fully evidence 
this overaccountability practice. 

The essence of our governance is to account for all the how-to’s in contrast to 
"what" the laboratories contribute. 

As a consequence the system is rife with: 

	-Hundreds of full-time equivalents are attending to issues per labora-
tory to see to the meeting of DOE requirements that are in excess of Federal, 
state and local regulations and/or are in excess of requirements for a 
comparable, commercial activity
	
	-Hundreds of thousands of pages of budget information documents 
are prepared and circulated throughout the system.  Many of the 
laboratories find themselves submitting their budget documents to well over 
one hundred offices. 
	
	-Department of Energy orders to the laboratories range from a few to 
a few hundred pages in length and are prescriptive to detail processes
	
	-There are some 30 thousand individual requirements embodied in 
these orders to certain of the major laboratories
	
	-Once an individual order has been determined as obliged to resolve 
a particular situation it is more often then spread  universally throughout the 
system without any differentiation as to the uniqueness of the initial concern.  
For example an employee of a contractor only indirectly related to the 
principal work of a laboratory was involved in an automobile accident.  This 
generated a prescription that all employees who drive their vehicle on 
laboratory affairs were obliged to take defensive driving lessons with the 
consumption of an inordinate number of hours and excessive dollars in 
unnecessary training costs. 
	
	-Auditors and inspectors often by the dozens descend often daily on 
many of the laboratories.  The laboratories have to staff up to be responsive 
to the engagement and then are obliged to spend a significant amount of 
time putting in place whatever are the prescriptions of these auditors.  
Virtually every audit that was accounted to the Task Force added a cost, 
versus saved a cost. 
	
	-Almost everyone must follow new rules and orders not necessarily 
relevant to their situation, if perchance a few have erred elsewhere. 
	
	-DOE Headquarters has insisted that copies of DOE terms and condi-
tions be attached to all file copies of literally thousands of small purchase 
orders in order to document that these terms and conditions had been 
transmitted to vendors. 
	
	-Procurement management directives have obliged the hiring of ad-
ditional support staff, vastly increasing written procedures and hiring of 
procurement consultants. 
	
	-Construction projects and operational and equipment activities are 
to be managed to various different tracks of regulations complicating the 
common sense approach to resolving the particulars of such functions way 
beyond what other institutions in society bear. 
	
	-The capital asset management process and condition assessment 
survey is a hornet's nest of complex documentation without cost benefit 
consequences. 
	
	-Senior audit and inspection officials state that they must concentrate 
on reviewing and insisting on processes, audits, etc. because there is to 
them little demonstrated "product" against which to evaluate if the labs are 
producing a knowledge value for the money appropriated.  Process is a 
surrogate of product. 
	
	-Department of Energy people report that many Congressmen 
believe that the Department of Energy should treat the oversight of employ-
ees of the private contractors just as if they were employees of the 
government. 
	
	-More controls are in the offing regarding overtime, pension costs and 
decisions regarding make or buy. 
	
	-From time to time the Congress or the Department allocates funds for 
a general research program and then put fences around what the money 
can be spent for. 
	
	-Congress and the Department often specify what it wants done but 
does not allocate the money for that new additional function. 
	
	-Funds are segmented to what are colloquially called "stove pipes" 
whereas the aggregation of funds would be far more effective and efficient 
allowing the people who know what the technology is all about to work out 
the allocations. 
	
	-Consortia are a recommended institutional way of the private sector 
interfacing with the laboratories.  AMTEX (American TEXtiles) is one such 
consortia.  It took scores and scores of CRADAs to be written in order to 
have a relationship with the one consortia.  Certain consortia that would 
want its work done most effectively in the laboratory system cannot get the 
work done in the appropriate laboratory. 
	
	-The system is input oriented versus output oriented. 
	
	-Each laboratory acknowledges that it has more people than it needs 
because of the Federal prescriptions and the inability to add the flexibility of 
assigning people in the manner that would be most productive. 
	
	-Environmental, safety and health objectives are worthy and all rea-
sonable ones should be accomplished.  The degree to which the Gov-
ernment is specifying how these are to be handled is beginning to absorb 
virtually as much funds as funds remaining for science.  
	
	-A laboratory wanted to outsource its cafeteria service.  The Govern-
ment obliged that the outsourcing of the 22 cafeteria workers required the 
laboratory to write a complete workforce restructuring plan,  in spite of the 
fact that the authorizing act for such was intended to deal with 
fundamental structuring or changes in missions versus a minor change in a 
department.  Incidentally, all of the 22 people would have been candidates 
to work for the outside supplier if that were to their and the supplier's best 
interest.
	
	-Everyone wants in on the act--headquarters, the DOE area office, 
the DOE field office, program offices of the DOE, the Defense Nuclear 
Facilities Safety Board (DNFSB), the Department of Labor's office of Federal 
Contract Compliance, the EPA, the General Accounting Office (GAO) and 
the state where the lab is located.  Each has oversight entities.  Each thinks 
that their audit is the most important.  Most audit without any coordination 
with others.  Some audits take as long as six months.  The number of auditors 
in an audit team vary greatly but has been as high as 150 people.  The 
major financial impact of this is not the cost of the auditor's time but the cost 
and lost productivity of those interfacing with the auditors.  This leads to an 
enormous escalation of cost.  Possibly the greatest negative effect is the 
affect on the motivation of the scientists and engineers, all of whom are 
loyal to their science and loyal citizens wanting to be able peers with their 
respected associates in the laboratory.  But we heard from any number of 
people the message that can be simply summarized that "more and more 
of us are more concerned  about our job than doing the job."  Too much 
time is distracted to the unpleasant and unproductive aspects of the job.  
An increasing number, though still a minority, lean to questioning the 
conditions of the job.  Good people are leaving. 
	
	-The Department of Energy acknowledges that waste management 
and environmental remediation programs are the most rapidly growing 
Department of Energy demand on funds.  To the extent that these 
obligations which derive from defense functions of decades ago could be 
more clearly segmented, the other major future interests including new 
science for environmental subjects, could stand alone. 
	
	-Starts and stops of assignments have caused an inordinate unpro-
ductive waste of funds.  For example, the mesas around Los Alamos are 
strewn with the skeletons of facilities that were started with much enthusiasm 
on the part of the laboratory, the Department of Energy and Congress but 
were prematurely terminated before completion because the annual 
funding appropriation could not be sustained.  Often these projects were 
more than 75 percent complete at the point of cancellation.  The annual 
programming of funds is a major waste.  Multiyear programming should in 
some fashion be accomplishable, providing the confidence of 
predictability. 
	
	-The very process of annually having to resell a program is an act of 
inefficiency. 
	
	-The total laboratory program (10 laboratories, $6 billion budget, 17 
thousand active R&D personnel, etc.) is  modest in size compared to many 
of the large corporations.  Any corporation that you would compare this to 
would have but a small fraction of audit costs compared to what is involved 
in the oversight of the DOE laboratories.  The laboratories are run by the 
same high quality class of honorable people (though they, like corporate 
people, make an occasional mistake or misallocation) and do not need to 
be overseen in the fashion that is prescribed.  Those in the private sector 
rarely audit and inspect their suppliers' business processes, and for the most 
part no corporation allows any of its customers to audit and inspect its ac-
tivities.  The private sector does respect the laws that apply specifically to 
financial accounts, safety factors, etc., and the government laboratories 
should be limited to the same class of oversight. 
	
	-Recently the Department has been engaged in a sincere interest to 
improve the contracting process aimed at having the contracts be 
performance-based.  Yet in the first major paragraph of the news 
announcement concerning performance-based management contracting, 
it says "the reforms would increase competition for DOE business, hold 
contractors more accountable for fines and penalties, reduce excessive 
outside attorney fees, require a specific performance criteria and measures 
on all contracts, impose stricter cost controls on expenses such as 
administrative support, maintenance, pensions, overtime and property 
management."  The document that explains the performance-based 
contract is scores and scores of pages long. 
	
	-Page 46 of the contract explanation document indicates that the 
Department's current information system does not provide the kind of data 
needed to manage contractors effectively.  The words convey:  the 
Department wants to manage. 
	
	-The document pleads the case that all the various contract 
administrators, inspector generals, audit agencies, etc. are under staffed 
and need more people. 
	
	-There has been an avalanche of DOE orders including 4,800 project 
orders and 8,400 Environment, Safety and Health (ES&H) orders with from 
200-400 oversight reviews per lab per year. 
	
	-There are at least 12 principal layers of management between the 
assistant secretary for defense programs down through the layers of DOE 
and the laboratory program management to the bench scientist working of 
a project financed through defense programs.  There are additional 
oversight and administrative chain of commands through the field offices 
which probably add two or three more layers. 
	
	-One array of difficulties with which DOE has not yet been able to 
deal properly is ironically self-inflicted.  Far too much influence has been 
ceded to non-regulatory advisory boards, such as the Defense Nuclear 
Facilities Safety Board (DNFSB).  Such organizations generate 
recommendations with no apparent cost / benefit analysis, resulting in 
significant unnecessary expenditures and productivity losses.
	
	-There is neither a mechanism within DOE to evaluate and stand 
against poorly-taken DNFSB edicts nor to ensure Department-wide 
compliance with those edicts judged appropriate.  The Board has itself 
noted this last defect. 
	
	-At Pacific Northwest Laboratory, for example, overhead costs of 
Environmental Safety and Health (ES&H) increased 40% over a four year 
period with no demonstrable improvement.  A study of 13 DOE labs 
indicated that ES&H funding increased 100% and manpower increased 50% 
between 1985 and 1990.  Safety performance was independent of funding 
and negative indicators (lost work days, radiation exposure, etc.) remained 
constant or increased. 
	
	-In many areas the regulations parallel rules already enforced by 
agencies outside of DOE under federal and state legislation.  Frequently 
they prove unnecessarily stringent.  As an example:  Radiological control of 
radiation sources at Lawrence Livermore National Laboratory requires 
sources 100 times smaller than a Coleman lantern mantle and 300 times 
smaller than a smoke detector to be treated under the same standards as 
larger sources. 
	
	-EG&G, the management and operations (M&O) contractor at Rocky 
Flats, recently spent about $500,000 to write a record of decision to 
document that no further action was required to close out one of the 
Individual Hazardous Substance Sites (Operable Unit #16), mostly free of 
mixed waste contamination, where no further pumping or digging was 
needed. 
 	
	-This was the result of an environmental gridlock involving the 
Comprehensive Environmental Response, Compenstation, and Liability Act 
(CERCLA), the Environmental Protection Agency (EPA) and the Colorado 
Dept. of Health, which DOE was unable to resolve. 

	-Requirements for maintaining the "safety envelope" at the Rocky Flats 
site, which among other matters involves 245,000 surveillances annually, 
preparing inspection reports and maintenance improvement records, costs 
the plant $100 million per year, a level that senior management considers 
"very unreasonable."  Many staff members echo the desire for a clarification 
of goals for the site.  Moreover while the delays mount, the experience base 
continues to degrade as seasoned employees retire or quit.






Appendix B: If GOCO System Is Obliged


If the authorities oblige that the GOCO system is retained, the Congress and the 
Department must improve operational efficiencies and motivational conditions of 
the federal system by correcting the policies and practices listed below.  If these 
are not completely revised the Congress/Department/Laboratory system is 
destined to bear excessive unaffordable, micromanaging costs and 
demotivational consequences.  It will follow that plan to deactivate and/or 
dispose of the laboratories at some liquidation value will be inevitable because 
the public will not countenance the high cost/low value output that will be 
destined. 


Base DOE Oversight on Laboratories' Performance

	-Replace compliance-based directives with simple, well-defined per-
formance measures.
	-Eliminate DOE approval of labs' internal procedure documents.
	-Eliminate DOE approval of individual transactions (e.g., in procure-
ment and compensation). 
	-Base audits and appraisals on serious risk.
	-Eliminate duplication of audits, appraisals, and reviews.
	-Reward success with decreased oversight.

Operate labs according to industry-wide regulatory standards

	-Eliminate DOE self-regulation.
	-Shift regulatory oversight and inspection functions to responsible 
federal agency.
	-Eliminate these functions in DOE and reallocate resources.


Consolidate roles of DOE oversight offices

	-Consolidate fragmented headquarters safety roles and responsibili-
ties.
	-Reduce vertical layering of responsibilities for general lab oversight.
		-	Delegate oversight to one contracting office per lab, with a well-defined, 
limited scope of authority.
	-Consolidate or eliminate field offices, at least.


Apply rational, consistent business management principles

	-Institute a multiyear budget process, for both authorization and ap-
propriation.
	-Standardize DOE's budgeting and financial reporting requirements 
across program offices:
		-	Offices have different criteria for schedule, format, type of budget data, or 
type of cost reporting.
		-	Cross-cut budgeting should be examined for appropriateness.
	-Empower labs to establish long-term supplier relationships.
	-Empower labs to locally determine "color of money", except for Con-
gressional mandates.


Manage lab infrastructure in a responsible fashion

	-Re-establish a strong, well-defined landlord function, with one landlord 
per lab.
	-Consolidate funding sources for infrastructure maintenance and im-
provement with each lab's DOE landlord.
	-Initiate a multiyear "get well" program for labs'  infrastructures.


Challenge labs to reduce costs

	-Allow the quality management programs to become fully applied 
without outside interference. 
	-Strengthen overhead-control efforts.
	-Outsource work based on good business practice for each site.
	-Re-engineer administrative processes to fully exploit benefits of modern 
information systems. 


Other

	-Simplify CRADAs much more.






Appendix C: Terms of Reference


Terms of Reference
Secretary of Energy Advisory Board Task Force on
Alternative Futures for the Department of Energy National Laboratories

Overview

The 1990s are a period of substantial change for the Department of Energy's (DOE) 
nine multi-program National Laboratories, particularly the Department's three 
nuclear weapons laboratories.  Sweeping geopolitical changes, limitations on 
nuclear weapons testing, increased attention to economic competitiveness, and 
the continuing demands of energy development and environmental quality--all 
within the context of tight federal budgets--are but a few of the factors that 
confront the DOE laboratories with challenges and opportunities for the future.   

The purpose for establishing the Advisory Board Task Force on Alternative Futures 
for the DOE Laboratories is to carefully examine options for change within these 
laboratories and to propose specific alternatives for directing the scientific and 
engineering resources of these institutions toward the economic, environmental, 
defense, scientific, and energy needs of the nation.  The Task Force should focus its 
initial efforts on developing a comprehensive and current understanding of the 
facilities, resources, core competencies, activities, and missions of the 
Department's multi-program national  laboratories, both as individual institutions 
and as a system.     The Task Force should also develop an early understanding of 
the national defense requirements that necessarily will play a major role in shaping 
the configuration of the defense laboratories for years to come, and should 
closely examine the unprecedented recent growth in collaborations between 
DOE laboratories and the private sector.

Once a fundamental understanding of these matters has been established, the 
Task Force should broadly explore critical issues facing DOE's multiprogram 
laboratories (and single-program laboratories, as deemed appropriate) and 
should examine alternative scenarios for future utilization of these laboratories for 
meeting national missions.  Among the alternative scenarios, the Task Force should 
specifically address options involving the possible redirection, restructuring, and/or 
closure of elements of the DOE laboratory system.  The Task Force should identify 
the costs and benefits to the nation of various alternative futures for the DOE 
multiprogram laboratories, and within one year (January 1995) should report these 
assessments along with recommendations, as deemed appropriate.



	Objectives


1.	The Task Force should develop a clear understanding of the roles played by 
the DOE multi-program laboratories in the research and technology development 
process.  Specifically, the Task Force should examine the roles of the laboratories in 
meeting public missions, in serving as an R&D provider to other agencies and the 
private sector, and in working with academia to advance fundamental science.  
This examination should include an assessment of the contribution of the DOE 
laboratory system to the overall national investment in science and technology, 
and a comparison of the activities of the DOE laboratories to the R&D focus of 
other government agencies, academia, and the private sector. 

2.	The Task Force should become well versed with the nuclear weapons-
related research, development, testing, and evaluation (RDT&E) needs for the 
nation over the coming decade, and the options for satisfying these needs.  
Specifically, the Task Force should closely examine the strategic planning efforts 
currently underway within DOE Defense Programs, particularly those efforts aimed 
at shifting the nuclear weapons safeguards program from underground nuclear 
testing to science-based stockpile stewardship.  

3.	The Task Force should  examine the current configuration of nuclear 
weapons RDT&E activities among Los Alamos National Laboratory, Livermore 
National Laboratory, and Sandia National Laboratories.  This should include an 
assessment of the strategy behind the current configuration, which involves 
purposeful redundancy to promote competition and peer review.  Alternatives to 
the existing configuration should be examined.

4.	The Task Force should assess the role of the National Laboratories in 
supporting economic competitiveness and contributing to the U.S. industrial R&D 
base.  This should include an examination of the opportunities and the 
mechanisms for the National Laboratories--as a system--to contribute to large 
partnerships with the private sector.

5.	With a current assessment of the roles and missions of the DOE multiprogram 
laboratories in mind, the Task Force should examine several options for the future 
of these institutions in terms of budgets, management, and mission assignments, 
including an analysis of possible costs and benefits of each alternative.  As part of 
the examination of costs and benefits, the Task Force should assess the ability of 
R&D institutions such as the DOE laboratories to adapt to varying levels of change.  
This analysis should assist the Task Force in recommending implementation options.


Acknowledgments


The Task Force members would like to acknowledge the support of a large 
number of people in the laboratories, the Department of Energy, the contractor 
organizations, and the affected communities, for their insights, information, and 
opinions.  In particular, we would like to thank Sean McDonald, Sean Headrick, 
John Clarke, Tom Jervis, and Susan Barisas, Frances Musgrove, and Mable Dawson 
for their significant contributions.
 The weapons laboratories are Lawrence Livermore National Laboratory 
(LLNL), Los Alamos National Laboratory (LAND), and Sandia National 
Laboratories (SNL).  LLNL and LAND are weapons design laboratories while 
SNL is the engineering laboratory.
 Brigadier General Anthony Tolin, USAF, Strategy and Policy, Joint Staff, private 
briefing on the Nuclear Posture to the National Security Subgroup of the Task 
Force, October 14, 1994.
 Steven Andreasen, Strategic and Nuclear Affairs, National Security Council, 
private briefing on Presidential Decision Directives to the National Security 
Subgroup of the Task Force, August 9, 1994.
 Current weapons designs are secure, safe and reliable.  There is no threat to the 
nation that would justify the development of a new nuclear weapon at this time.  
If weapons in the stockpile should develop problems that cannot be resolved, and 
that raise doubts about their reliability or safety, consideration could be given to 
the option of replacing them with modernized versions of earlier, very robust, well-
tested designs.  However, the safety and reliability record of the stockpile indicates 
the successful resolution of all past weapons problems; any future reliability or 
safety problems should be first analyzed and solved -- if possible -- by the 
replacement of specific components or addition of new safety features if needed.
 The Jason Stewardship report entitled Science Based Stockpile Stewardship, 
August 10, 1994.
 Strategic Energy Research and Development Task Force, Chaired by Daniel 
Argon, President, Cambridge Energy Research Associates.
 Technology for a Sustainable Future, National Science and Technology Council, 
1994
 
"DOE Needs to Expand Use of Cleanup Technologies." GAO/RCED-94 - 9205.
   "Cleaning Up The Department of Energy's Nuclear Weapons Complex," The 
Congress of the United States, Congressional Budget Office, Washington, DC.  
May 1994.  This reference contains an extended discussion of DOE 's managerial 
practices, its approach to risk assessment and to the incorporation of new 
technologies on remediation efforts.
 
Ibid
 


For example, after the forced shutdown of Rocky Flats, in the fall of 1989, acidic 
plutonium solutions were left in a half dozen tanks in one building, with 
concentrations up to 125 grams of plutonium per liter.  They remain there to this 
day, with seals and gaskets deteriorating and occasional leaks occurring.  It would 
have required 2 weeks to one month to process and eliminate the immediate risk.  
There is 70 miles of piping containing Pu-nitric acid solution with 30 kg of Pu in 
them.
		
 
  Business Week, Aug. 2, 1993.
 
National Science Board, Science and Engineering Indicators - 1993, Appendix 4-
11, p. 346.  The data referenced here are obtained from NSF-conducted surveys 
and should be interpreted with caution since DOE does not budget its research 
according to the categories used in the surveys.  In reality, it is sometimes difficult 
to make the distinction between basic and applied research in those laboratories 
where the work is mainly applied R&D.
 The same preference for the laboratories is true of the DOE R&D budget as a 
whole.  The majority (62%) of all DOE-sponsored research and development is 
done in the DOE laboratories, with most of the rest being done at the universities 
(9% ), federal laboratories
(8%) and industry (18%). 
 
These data were obtained from the responses of nine laboratories to a survey 
questionnaire prepared on the Panel's behalf.  (AGNAIL did not respond to the 
survey but does very little basic research.) The survey used the same definition of 
"basic research" that is used by the National Science Foundation:  òThe objective 
of basic research is to gain more complete understanding of the subject under 
study, without specific applications in mind.  In industry, basic research is defined 
as research that advances scientific knowledge but does not have specific 
immediate objectives, although it may be in fields of present or potential 
commercial interest.ó  An independent GAO survey of ten DOE laboratories found 
that 16% of their total R&D fell in the basic research category.  The laboratoriesõ 
responses to the Panelõs and GAO's surveys indicate that they may see their R&D 
activity as more applied in nature than do the  DOE respondents to the NSF survey 
referred to in Note 2. 
 The panel attempted to determine in what proportions the different kinds of basic 
research described in the preceding paragraphs occur at the laboratories.  
According to the results of the survey carried out by the panel, basic research that 
is related to large user facilities accounts for 55% of all basic research at the 
laboratories; basic research that involves large interdisciplinary teams but that is 
unrelated to large user facilities accounts for another 34%; and general/single 
investigator basic research of the type most similar to university research accounts 
for the remaining 11%.
 Richard Nelson, Richard Rosenbloom, and William Spencer, "Shaping a New Era," 
November 1994 (DRAFT)
 Post-CRADA follow-up work at the laboratories would be classified as "work for 
others", for which the industrial partner is required to pay the full cost.  Many 
industrial partners would at that point be inclined to pull the work back into their 
own facilities.  Since the laboratories would then lose their DOE-budgeted CRADA 
financial resources, in the absence of independent review there might be a 
tendency for valid and successful CRADAs to continue beyond the completion of 
technology transfer and into product development or some other industrial 
activity. 
 A technological development plan which outlines, over time, the evolution 
of technological capabilities and provides milestones by which progress can 
be measured.
		
 
Fortune Magazine, November 14, 1994, pg. 146








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