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February 13, 2003
House Committee on Science
Testimony of Robert Card, Under Secretary of Energy,
Science, and Environment, Department of Energy, on The DOE's FY 2004 Budget Submission

Introduction

Mr. Chairman, Members of the Committee, it is a pleasure to join you today to present details on the Department of Energy's FY 2004 budget submission. The Department appreciates the support of the chairman and the members of the committee over the past years and I look forward to working with you to ensure this nation stays at the leading edge in science and technology in the 21st Century.

As Secretary Abraham noted recently, the Department has an "an ambitious, long-term vision of a zero-emissions future free of reliance on imported energy." As we look to the carbon free generation of electricity and hydrogen, it is clear that there is but one path open to us. We must call upon science, technology, and the research talents in our national laboratories, universities, and industry to help us improve and move beyond today's energy choices.

This year's budget demonstrates that the Department takes its responsibilities toward science and technology seriously because we take our responsibility toward national security seriously. Secretary Abraham has made clear that all missions at our Department flow from our core mission to support national security. We have, therefore, taken a deliberate and integrated approach to our research and development portfolio, using the strengths of all our programs to address this central mission. Clearly, environmental security and economic security underpin national security and each is sustained by science.

What is more, there is only one way to build an integrated budget and that is to engage in a vigorous and disciplined planning process that forces programs to set priorities. I think we have done that in this budget submission.

Mr. Chairman, consider how key initiatives undertaken in the FY2 04 budget are mutually supportive of the Department's overarching mission and reflect the need to set priorities:

• The President's Hydrogen Fuel Initiative - a major effort toward zero emissions and energy independence -- looks toward critical research and development efforts to develop fuel cell technology, and to find ways to produce and distribute hydrogen.

• Our request for carbon sequestration, a critical effort in our climate change program, is forty percent greater than last year. Here too, we look to science and technology, some of it extraordinarily exciting, to help us address a host of concerns.

• This year's request represents a major restructuring of our technology programs focused on the nuclear fuel cycle. With our Advanced Fuel Cycle Initiative the Secretary is challenging our department's best scientists to help devise a new approach to establishing a safe, sustainable, and proliferation resistant future for nuclear energy. Our nuclear programs are also integrated across DOE R&D portfolio, including improving the repository at Yucca Mountain, and will support our hydrogen fuels initiatives.

• We are also committed to leapfrogging today's energy choices with advanced concepts such as fusion. The President has announced that we will enter negotiations on ITER, to explore the next critical step in bringing electricity from fusion energy to the grid. If fusion proves successful, it could be the dominant new energy source for the end of this century and beyond.

• The Department is continuing its work as a critical part of the President's initiative on nanoscience. As the Chairman has noted, the Department is a major contributor in the nanotechnology field, and we intend to continue our leadership role by fully funding the construction of five nanoscience centers. These will be unique and essential facilities to help us realize the remarkable promise of nanotechnology.

These initiatives work together. For example, materials work from nanoscience will contribute to advanced fuel cell work, and fusion will one day perhaps give us the hydrogen we need to run those fuel cells.

We are fortunate to have a strong and well recognized global technology leadership role. As will become clear in the testimony that follows, many of the technologies that contribute to energy independence also contribute to reducing greenhouse gas emissions. The President's National Climate Change Technology Initiative (NCCTI) will help inventory and prioritize all climate change activities within the $1.6 billion worth of technology R&D that is included in the scope of the Climate Change Technology Program (CCTP), including clean coal, natural gas and other carbon management activities in fossil energy R&D. Within the CCTP the National Climate Change Technology Initiative (NCCTI) Competitive Solicitation program the budget requests $40 million to competitively award cost-share projects to research and develop technology that can help avoid, reduce, or sequester, greenhouse gases emissions.

Let me assure the committee that we recognize that all programs in the Department, not just these initiatives, must be managed to provide the taxpayer with the maximum benefit. We take the President's Management Agenda very seriously. Each of the programs at the Department has undergone, or is currently working on, a major restructuring, as well as bringing its programs in line with critical performance measures.

Before addressing the specifics of our research and development programs for FY2004, I would like to point out that research underpins almost every major program activity in the Department. Scientific research is the key to ensuring the reliability of our nuclear deterrent, and to the contributions that our national laboratories are making to counter-terrorism. It was also the key to the decision to move forward with the Yucca Mountain site as a repository for nuclear waste, a decision supported by 20 years and $4 billion worth of scientific study conducted by some of the world's preeminent scientists and carefully reviewed by outside bodies, including the International Atomic Energy Agency.

Let me now review the program areas within my area of responsibility in greater detail.

The Office of Science

Overview. The FY2004 budget request for the Office of Science supports the President's goal of ensuring continued U.S. leadership in science, and will enable the Office of Science to continue to support the Departments' missions in energy, environment and national security. Our economy, our energy security and our national security depend upon scientific discovery, which is the driver for technological innovation, and the Office of Science is a vital part of the Nation's scientific base. It is the largest single funding source for basic research in the physical sciences, and has provided approximately 40 percent of all federal funds in this area over the past decade. It is also the steward, and by far the principal funding agency, of the nation's research programs in high-energy physics, nuclear physics and fusion energy sciences, as well as being the federal government's largest single funder of materials and chemical sciences.

The Office of Science also supports unique or critical pieces of U.S. research in scientific computation, climate change, geophysics, genomics, and the life sciences. This research is conducted at both the Department's national laboratories and at approximately 250 universities nationwide. The Office of Science manages the construction and operation of some of the nation's most advanced research and development facilities - a vital part of the Nation's scientific infrastructure used by over 18,000 researchers annually.

The Department is aware of its obligation to manage these important resources well and to provide maximum benefit to the Nation. The Administration's FY2004 evaluation of Office of Science found that they had clearly defined purposes and were generally well managed, and has also cited our process of "Lehman Reviews" of construction projects as a "…widely recognized effective practice." We are also automating many of our routine operations and by the end of FY2004 100% of grant and contract proposals will be received electronically by the Office of Science, 65% of purchase orders will done electronically, and 80% of field work proposals will be processed electronically - including 100% of new projects. I would also note that the effectiveness of the management of our scientific programs is attested to by a history of success, the most recent example being the award of the 2002 Nobel Prize in Physics to Dr. Raymond Davis for his pioneering observations of neutrinos from the Sun, and the stunning discovery of neutrino mass and neutrino transmutations. We share this success proudly with the National Science Foundation, which also supported Dr. Davis's research.

The Office of Science is now in the process of implementing a restructuring to improve oversight of our laboratories by removing a layer of line management, and instituting clear chains of responsibility in accordance with the principles of the President's Management Agenda.

The Office of Science FY2004 budget request is $3.311 billion, compared to the $3.264 billion requested in FY2003. This provides an effective increase for science of 4.5% when the ramp-down in construction projects is considered, allowing us to increase support for high priority scientific research, continue operation of our large scientific user facilities, keep existing construction projects on schedule, and support new initiatives.

Office of Science research programs are managed in six major areas, and also include a restructured and enhanced effort in science education:

Fusion Energy Sciences. On January 30th, President Bush announced our intention to join the ITER project. The Department of Energy is the lead U.S. agency in this effort. ITER will allow us to explore the physics of a burning plasma - the essential next step in realizing the promise of commercially available fusion power. In 1997 the U.S. decided to allow the agreement covering U.S. participation in ITER to expire. At the time, the U.S. government had concerns about the scale of the ITER program and the ability of established management and financial structures to protect the U.S. taxpayer. In the meantime, the program has been rescaled and rebudgeted. A recent "Lehman review" of the management and cost estimates at ITER combined with scientific reviews performed by the National Research Council and DOE's Fusion Energy Science Advisory Committee have provided a strong basis for President Bush's January 30th decision to join the ITER negotiations.

We have dedicated $12 million within the FES program budget for FY 2004 to support research directly tied to our participation in the ITER project.

The Office of Fusion Energy Sciences will also continue its other programs of research to advance plasma science and fusion science, including its partnership in basic plasma science with the National Science Foundation. It will continue the operation of DIII-D, Alcator C-Mod and the National Spherical Torus Experiment and investigate alternative fusion concepts that may improve the economic or environmental possibilities for fusion energy. The Office of Fusion Energy Sciences will also continue its basic research in inertial fusion energy in concert with the National Nuclear Security Administration.

As the committee is aware, fusion energy has many potential advantages over current methods of electricity generation, not the least of which is a possible future contribution to the hydrogen-based economy through the emission-free production of hydrogen.

Advanced Scientific Computing Research. The Office of Advanced Scientific Computing Research provides the high performance computational and networking resources that are indispensable tools for discovery. The capabilities of terascale computing are transforming the conduct of science, bringing scientific simulation through computational modeling to parity with theory and experiment as a scientific tool. The Office of Advanced Scientific Computing Research also funds basic research in mathematical methods and computer science that enable scientists to more effectively use these resources. Every Energy Science and Environment mission area is likely to benefit from scientific insights generated through computational modeling on high end supercomputers in areas ranging from combustion processes to design of new materials to the movement of wastes and other contaminants through the environment.

The Office of Advanced Scientific Computing Research is at the center of efforts to realize the full potential of scientific simulation to solve mission related problems. It will support the Scientific Discovery through Advanced Computing program, a set of coordinated investments that cross-cuts Office of Science research programs. This program is a multidisciplinary effort involving teams of mathematicians, computer scientists, and application area scientists working to develop a new set of scientific simulation codes that can fully exploit today's terascale computing resources.

In FY2004, $14 million is dedicated to a new Next Generation Architecture program to optimize computer architecture to meet the special requirements of scientific problems. This effort will include both evaluation of the impact of alternative architectures on application performance, and software research on next generation operating systems.

The Office of Advanced Scientific Computing Research will continue to support existing research programs and facilities, such as the National Energy Research Scientific Computing Center at Lawrence Berkeley National Laboratory, now being upgraded to double its capability to support leading edge science.

Basic Energy Sciences. The Office of Basic Energy Sciences is responsible for construction and operation of the world's premier suite of large scientific user facilities, and is a principal Federal sponsor of fundamental research in the areas of materials sciences and engineering, chemistry, geosciences, and bioscience as it relates to energy. In FY2004, the request for the Office of Basic Energy Sciences will increase funding for the President's initiative in nanoscience by $64 million to $193 million. This will allow construction to proceed on a Nanoscience Research Center at Oak Ridge National Laboratory, as well as new construction of Nanoscience Research Centers at Lawrence Berkeley National Laboratory and Sandia National Laboratory in partnership with Los Alamos National Laboratory.

It also provides Project Engineering Design funding for an Nanorscience Research Center at Brookhaven National Laboratory and funds a Major Item of Equipment for a Nanoscience Research Center at Argonne National Laboratory, where the State of Illinois is funding the construction of the building. When complete, these centers will enable the nanoscale revolution by co-locating multiple research disciplines and a wide variety of nanoscience instrumentation, and their siting near existing light sources or neutron sources will allow rapid characterization of newly fabricated materials. This centralization of resources will provide "one-stop shopping" for scientists who now must often go to widely dispersed facilities to complete their research.

The FY 2004 budget also provides for continued research in materials science and engineering, chemistry, geosciences and energy bioscience as well as high level operation of existing user facilities. It continues funding for construction of the Spallation Neutron Source, which, following a rebaselining and rescoping exercise in 2001, is now on budget and schedule for completion in June of 2006. Our request will also fund project engineering design work for the proposed Linac Coherent Light Source, a 4th generation light source to provide very short pulse x-ray light which is orders of magnitude higher in intensity than today's synchrotron radiation light sources, offering unprecedented opportunities to, for example, observe the dynamics of chemical reactions to develop a deeper understanding of chemical processes.

Biological and Environmental Research. The Office of Biological and Environmental Research supports fundamental research in climate change, environmental remediation, genomics, proteomics, radiation biology, and medical sciences. The FY2004 budget provides $59 million, an increase of $24 million for the continued growth of the Genomes to Life program, and $25 million, an increase of $22 million for the Climate Change Research Initiative. The Genomes to Life program will develop new knowledge about how organisms grow and function and will marry this to a national infrastructure in computational biology to build a fundamental understanding of living systems. The thrust of Genomes to Life is aimed directly at DOE concerns: developing new sources of energy; mitigating the long-term impacts of climate change through carbon sequestration; cleaning up the environment; and protecting people from adverse effects of exposure to environmental toxins and radiation.

The Climate Change Research Initiative will extend research in climate modeling, atmospheric composition and the regional impacts of climate change. Under the integrative and strong leadership of the Department of Commerce, our office has concentrated on fundamental science to address critical climate issues. Work on the carbon cycle will investigate what fraction of carbon dioxide emissions are taken up by terrestrial ecosystems. Beginning in FY04, ecological research efforts will begin to bridge the knowledge gap between our understanding of molecular-level effects and the responses of entire ecosystems. Ultimately, this knowledge will enable us to predict reliably how ecosystems will react to changes in our environment.

In FY04 the Office of Biological and Environmental Research will continue to explore new clean-up strategies, including bioremediation and treatment of radioactive wastes. The goals of the Environmental Management Science Program, transferred in FY 2003 from Environmental Management, are to develop and validate technical solutions to complex problems, provide innovative technical solutions where there are none, and lead to future risk reduction and cost and time savings. The Environmental Management Science Program request of approximately $29 million in FY2004 will continue to support these goals, but with increased focus on integrated, multidisciplinary research to provide decision-makers better information on which to base their decisions. The budget request for the Office of Biological and Environmental Research also provides continued support for the Environmental Molecular Sciences Laboratory, a facility that brings state-of-the-art experimental and computational capabilities to the environmental community to improve our understanding of complex molecular interactions in the environment and our ability to predict contaminant behavior

Finally, the Office of Biological and Environment Research will continue to take advantage of the insights and expertise that result from its work across many scientific disciplines-materials science, biology, physics, and computation-to provide the medical community with novel devices to detect, diagnose, and treat disease.

High Energy Physics. The High Energy Physics program supports almost 90 percent of U.S. research in high energy physics that is coordinated with the research of the National Science Foundation high energy physics program through a jointly chartered advisory committee, the High Energy Physics Advisory Panel. This research has the goal of developing a deeper understanding of the basic nature of matter, space time and energy. The FY2004 request will fund continued world leadership in this research. We will continue to pay very close attention to luminosity concerns at the Tevatron and Fermi Laboratory will also continue construction of the NuMI/MINOS experiment, which is now on schedule and within budget, following a rebaslineing exercise in 2002. The B-Factory at Stanford Linear Accelerator Center, operating well above its design luminosity, will also continue its program of research to understand why there is a preponderance of matter over antimatter, a critical question in the evolution of the universe. As part of an increasing emphasis on non-accelerator-based research projects, funding will be increased for the Supernova Acceleration Probe at Lawrence Berkeley National Laboratory, a space-based experiment to explore the nature of "Dark Energy," an unknown force that is accelerating the expansion of the universe.

Nuclear Physics. The Departments' nuclear physics research program is the principal sponsor of nuclear physics research in the U.S., providing 85% of Federal support, and is coordinated with the research of the National Science Foundation's nuclear physics program through a jointly chartered advisory committee, the Nuclear Science Advisory Committee. This research seeks a deeper understanding of the properties of nuclear matter. For FY 2004, a primary focus of the program will be to exploit the capabilities of the world's finest experimental facilities for nuclear physics. At the Brookhaven National Laboratory's Relativistic Heavy Ion Collider, researchers will continue efforts to create and study the plasma of unconfined quarks and gluons believed to have existed a microsecond after the "Big Bang." At the Continuous Electron Beam Accelerator Facility located at the Thomas Jefferson National Accelerator Facility, high energy beams of electrons will probe the internal structure of nucleons. To optimize the utilization and scientific productivity of these and other experimental facilities required some difficult decisions. As a result, in a decision informed by the priorities recommended by the Nuclear Science Advisory Committee, operation of the 88-Inch Cyclotron at Lawrence Berkeley National Laboratory will be terminated.

Recent results from neutrino physics experiments have provided indications of new physics beyond the Standard Model, and funding has been increased to support non-accelerator-based experiments such as the international collaborations at the Sudbury Neutrino Observatory, KamLand and elsewhere for further investigation of these results.

Workforce Development for Teachers and Scientists. Formerly known as "Science Education" and budgeted as a subprogram in the Science Program Direction budget, this program will continue the existing activities of the Science Education program. It will also begin a pilot program at Argonne National Laboratory, funded at $1 million, to exploit the resources of the national laboratories to provide professional development for K-14 science and mathematics teachers, who are the key to fostering interest in mathematics and science among students. Teachers will be competitively selected and matched with laboratory mentors working in their field of instruction. They will then spend 4-8 weeks at a laboratory performing research mentored by both laboratory scientists and "master teachers" who can help them transfer the laboratory research experience to the classroom. This will be the first step in a continuing relationship with the laboratory that will include additional one week on-site mentoring sessions and continuing communication. Intensive follow-up and performance measures will be applied to assess the results of this pilot.

This initiative, in response to the President's call for a "qualified teacher in every classroom," will bring some of the Nation's finest scientific and technical resources to bear on improving the quality of instruction in science and mathematics to address a critical national problem - developing a technically trained and educated workforce for the 21st century.

The Office of Nuclear Energy, Science and Technology

Overview. Over the last thirty years, nuclear power has risen to become one of the most important sources of electric energy in the United States and at the same time, among the most operationally economic. The benefits of nuclear power as a clean, reliable and affordable source of energy are a key to the economic and environmental underpinnings of this Nation. A central mission of the Department's nuclear program is to help enhance the basic technology and, through some of the most advanced civilian technology research conducted today, chart a course to the next leap in technology. In FY 2004, we are proposing a $388 million investment in nuclear research and development and for the Nation's nuclear science, technology and education infrastructure, a nearly twenty percent increase over last year's request.

This budget request responds to the President's priorities to deploy new generation capacity to fortify U.S. energy independence and security while making significant improvements in environmental quality. It builds on the important work started over the last two years to deploy new nuclear plants in the U.S. by the end of the decade, to develop advanced, next generation nuclear technology, to strengthen our nation's nuclear education infrastructure, and proposes exciting new priorities -- a new Nuclear Hydrogen Initiative to use high temperature nuclear energy systems for clean hydrogen production as part of the President's Hydrogen Fuel Initiative and the Advanced Fuel Cycle Initiative, research aimed at developing proliferation-resistant fuel treatment and fuel cycle technologies that can reduce the volume and toxicity of commercial spent nuclear fuel and maximize energy from nuclear fuel.

Also, during FY 2002, the Department proceeded to implement the President's Management Agenda, including a major reorganization to better reflect the Administration's priorities, improve overall management and reduce the number of primary organizational units from eight to three. To assure overall accountability, PMA performance measures were cascaded from the Director, through the management to the staff. High emphasis has also been placed on development of meaningful R&D investment criteria and their application to the nuclear research initiatives. The nuclear program has successfully recruited and hired new junior professional staff and is working to put to new senior management team in place at the Idaho Operations Office, who will oversee nuclear R&D at INEEL as well as completion of the cleanup mission.

Let me expand in more detail on the Department's nuclear energy initiatives, and the linkages of these initiatives among one another.

Advanced Fuel Cycle Initiative. Of the issues affecting future expansion of nuclear energy in the U.S. and worldwide, none is more important or more difficult than that of dealing effectively with spent nuclear fuel. After a long and difficult process, the country is moving forward with a geologic repository, and we are on schedule to submit a license application to the Nuclear Regulatory Commission by the end of 2004.

With these successes, we are able to pursue research that can optimize the use of the first repository and possibly reduce the need for future repositories. For years, countries around the world have pursued advanced technologies that could treat and transmute spent nuclear fuel. For the last three years, the U.S. has been a participant in this research. As one of the Secretary's capstones, the FY 2004 budget request proposes an aggressive research and demonstration program, the Advanced Fuel Cycle Initiative, with an investment of $63 million in FY 2004 to continue exploring advanced, proliferation-resistant nuclear fuel treatment and transmutation technologies that can reduce volume and toxicity of spent nuclear fuel for a geologic repository. If successful, these same technologies offer benefits of enhancing national security by reducing inventories of commercially-generated plutonium and enhancing energy independence by recovering the energy value contained in spent nuclear fuel.

The Department is proposing a research program leading to a demonstration of proliferation-resistant fuel treatment technology to reduce the volume of high level waste, and development of advanced fuels in the 2015 time frame that could enable consumption of plutonium using existing light water reactors or advanced gas reactors. With the President's request, the Department will continue work toward demonstration of proliferation-resistant fuel treatment technology and continue design of transmutation fuels for future use with current reactor technologies.

However, for the Advanced Fuel Cycle Initiative to be successful, advanced fuel treatment and transmutation research and development must be integrated with the development of Generation IV nuclear energy systems, particularly with those reactor technologies that can produce very high energy neutrons that would be needed to transmute a wide variety of toxic radioactive species. To support this goal, the Advanced Fuel Cycle Initiative will develop the advanced proliferation resistant fuels and fuel cycle systems for Generation IV reactors.

Generation IV Nuclear Energy Systems. Two years ago, we launched the Generation IV program to develop advanced reactor technologies for commercial deployment after 2010 but before 2030. These advanced reactors offer significant advances in sustainability, proliferation-resistance, physical protection, safety and economics. Development of these reactors is being pursued by the Generation IV International Forum, a group of ten leading nuclear nations (United Kingdom, Argentina, Brazil, Canada, France, Japan, Republic of Korea, Republic of South Africa, Switzerland, and the United States), who last year selected six promising technologies for joint research, development, and demonstration. While the Department has not yet decided upon which of these technologies it will eventually focus, all of the technologies are of considerable interest. The six innovative, next-generation technologies include two gas-cooled reactors, one water-cooled, two liquid-metal-cooled reactors, and a molten salt-based reactor concept.

Key research objectives for these technologies will include such activities as demonstrating advanced fuels and materials. The goal of the initiative is to resolve the fundamental research and development issues necessary to establish the viability of these concepts. By successfully addressing the fundamental research and development issues, the concepts are highly likely to attract future private sector sponsorship and ultimate commercialization. In FY 2003 and FY 2004, the Department will establish international partnering agreements to guide joint research and begin research and development on several of the reactor concepts, including very high temperature reactors that would be suitable for efficient production of hydrogen.

Nuclear Hydrogen Initiative. Generation IV is closely linked to our new Nuclear Hydrogen Initiative, aimed at demonstrating economic commercial-scale production of hydrogen using nuclear power no later than 2015. The use of hydrogen using high temperature advanced reactors such as advanced gas-cooled or liquid metal-cooled reactors can provide the heat necessary for the process. These technologies offer the potential for large-scale, emission-free, hydrogen production capability needed to fuel a hydrogen economy. Today, through electrolysis, we can convert water to hydrogen using electricity but we believe that for the future, high temperature nuclear energy systems coupled with thermo-chemical water splitting processes offer a more efficient technology for production of large quantities of hydrogen, without release of greenhouse gases.

The hydrogen initiative grew out of the success of our Nuclear Energy Research Initiative, in particular, two investigator-initiated projects that identified a number of advanced reactor concepts capable of producing large quantities of hydrogen with high efficiency and low cost. Since then, we have awarded an additional three projects and the International component of the Nuclear Energy Research Initiative has awarded one research project studying nuclear production of hydrogen. The Nuclear Hydrogen Initiative builds on the research from the Nuclear Energy Research Initiative and International Nuclear Research Initiative to demonstrate the ability to use nuclear to produce hydrogen with high efficiency and low cost. In FY 2004, we propose to invest $4 million to begin this initiative by developing a Nuclear Hydrogen Technology Roadmap and to conduct laboratory-scale demonstration of some of the key processes involved in nuclear hydrogen production.

Nuclear Power 2010. The President's budget supports continuation of Nuclear Power 2010 in FY 2004 to demonstrate, in cost-shared cooperation with industry, key regulatory processes associated with licensing new nuclear plants in the U.S. In FY 2004, the requested funds would support the activities associated with submitting and achieving NRC approval of early site permits and development of Combined Construction and Operating License applications.

Most, if not all, of our research initiatives involve participation by U.S. universities. The Advanced Fuel Cycle Initiative, for example, proposes to resume a fellowship program aimed at attracting graduate and doctoral students to the discipline of transmutation science. Other programs, like the Nuclear Energy Research Initiative, sponsor research conducted in large part by universities as well as national laboratories and the private sector.

University Reactor Fuel Assistance and Support. For years, the Energy Department has sponsored an initiative that supports nuclear science and technology educational infrastructure through our University Reactor Fuel Assistance and Support initiative. The need for trained and qualified nuclear scientists has not diminished over the years, and in fact, because of increasing retirements in the nuclear field, demand today exceeds supply.

We are very pleased that the President's budget includes $18.5 million for this program for fellowships, scholarships, nuclear engineering research, and for critical support to university research reactors. In FY 2002, the Department launched the Innovations in Nuclear Infrastructure and Education program, encouraging universities to form ground-breaking partnerships with national labs, the private sector, and other universities to strengthen nuclear engineering education and optimize the use of research reactors. In FY 2002, DOE issued awards to four consortia of universities and their partners. With an additional $1 million requested in FY 2004, we hope to support additional awards.

INEEL -- DOE's Command Center for Nuclear R&D. Finally, this budget supports the Secretary's realignment of the mission of the Idaho National Engineering and Environmental Laboratory to focus the future of the site on nuclear research and development. As the Department's leading center of nuclear research and development, this laboratory is the "command center" for our efforts to develop advanced reactor and fuel cycle technologies, including development of space nuclear power and propulsion technologies.

While the nuclear energy program involves the collective talents of universities, the private sector, international partners, and our national laboratories -- Argonne, Los Alamos, Sandia, and Oak Ridge among them -- the rebuilding of the Departments' nuclear program that is underway today for our Nation's long-term energy security will not possible without the dedicated scientists, engineers and supporting staff of the Idaho National Engineering and Environmental Laboratory. Clearly, environmental cleanup will remain a major focus of the Department for the near-term but real progress is being made that will clear the way for expansion of nuclear research and development. With this year's budget, $110 million has been transferred from the environmental cleanup program to the Department's nuclear program to manage laboratory infrastructure and security.

The Office Energy Efficiency and Renewable Energy

Overview. The overall FY2004 budget for the Office of Energy Efficiency and Renewable Energy is $1.320 billion, compared to $1.319 billion requested in FY2003. The request reflects support to carry out National Energy Policy recommendations, the Department's mission, program priorities, and the Energy Efficiency and Renewable Energy Strategic Program Review recommendations.

The FY 2004 Budget also reflects the new organization within the office. Two years ago, the Office of Energy Efficiency and Renewable Energy was divided into 31 programs, in 17 offices, stove piped into 5 market sectors. There were multiple overlapping layers of management; and duplicative and inconsistent business systems that generated significant inefficiencies and made it difficult to ensure accountability.

In response to the President's Management Agenda, we launched a dramatic restructuring of the program in April 2002. This restructuring eliminated the five market sectors and 17 offices, streamlined 31 programs into 11, eliminated up to four management levels, and centralized administration functions into a single support organization with a focus on developing consistent, uniform, and efficient business practices. This is the most dramatic restructuring of the Office of Energy Efficiency and Renewable Energy in at least a dozen years and arguably in its history.

The restructuring combined all the hydrogen and fuel cell activities, formerly scattered across two market sectors and three programs, into a single program for greater efficiency.

The restructuring also combined all the bioenergy-related activities, formerly scattered across three market sectors and three programs, into a single program focused on advanced biorefineries.

The FY 2004 budget is fully aligned with the new management structure and strategic goals and together they will provide greater synergy and increased efficiency and productivity in research and development and deployment activities.

Research and development and technology deployment efforts supported by the FY 2004 budget will provide Americans with greater freedom of choice of technology, while providing increased energy security, and reducing financial costs and impacts on the environment.

The FY 2004 budget has been developed with these challenges and opportunities in mind.

Hydrogen Fuel Initiative. The big news in the FY 2004 budget is, of course, the President's Hydrogen Fuel Initiative. The President's Initiative directly supports EERE's number one priority to dramatically reduce or even end dependence on foreign oil.

America currently depends on foreign sources for 60 percent of its oil - a dependence that is projected to rise to 70 percent by 2025. Since two thirds of the oil we consume is used for transportation, we must focus on alternative means of fueling transportation from domestic resources if we ever expect to reverse this trend.

In his recent State-of-the-Union address, President Bush announced a new research and development initiative focused on hydrogen that, in conjunction with FreedomCAR launched last year, will help reverse America's growing dependence on foreign oil and expand the availability of clean, abundant energy.

The President's Hydrogen Fuel Initiative will accelerate research and development on hydrogen production, delivery, storage and distribution, and establish the necessary safety-related codes and technology standards. The initiative also will fund limited "learning" demonstrations of fuel cell vehicles and hydrogen infrastructure so that these technologies can be validated under real world conditions. When the President's vision of a child born today driving a hydrogen fuel cell vehicle is achieved, hydrogen fuel cells also could power our Nation's homes, schools and businesses.

The hydrogen needed to fuel these vehicles and stationary power sources is domestically available in abundant quantities as a component of natural gas, coal, biomass and even water through electrolysis using renewable or nuclear power. In the future, we may well also look to fusion energy to power a hydrogen economy. The challenge is to economically produce, deliver, store and distribute hydrogen for use as a consumer fuel in a cost-effective and environmentally-sound way, and to engage the broader oil, energy and power companies in this effort.

To support the President's vision we need to make the necessary research and development investments to develop vehicles powered by hydrogen fuel cells and the infrastructure to support them. The government role will be to fund and coordinate the high-risk R&D work of numerous private sector partners and our national network of science laboratories. Government coordination of this undertaking will help resolve one of the difficulties associated with development of a commercially viable hydrogen fuel cell vehicle: the "chicken and egg" question. Which comes first, the fuel cell vehicle or the hydrogen production and delivery refueling infrastructure to support it? The President's Hydrogen Fuel Initiative, in conjunction with the FreedomCAR partnership, answers the question by proposing to develop both in parallel; that is, to augment the already significant investment in vehicle technologies with new investments in hydrogen and fuel cell technologies. By so doing Federal investments can help to advance commercialization of hydrogen fuel cell vehicles and infrastructure by 15 years, from 2035 to 2020.

To meet this challenge, the President's FY 2004 budget commits $1.2 billion for hydrogen and fuel cells over five years ($720 million in new money); including in FY2004 $181 million for the DOE (mostly EERE) and 0.7 million for the Department of Transportation.

The Hydrogen Fuel Initiative enhances and complements the FreedomCAR partnership announced last year. FreedomCAR is a public-private partnership with U.S. automakers to accelerate the development of practical, affordable hydrogen fuel cell vehicles. The funding request for the Hydrogen Fuel Initiative and FreedomCAR combined will total $1.7 billion over five years.

The funding request for the vehicle technologies program under the FreedomCAR umbrella increases from $74.4 million in our FY 2003 budget to $91.1 million in FY 2004. This will increase the research and development emphasis on battery and materials technologies critical for fuel cell and combustion hybrid vehicles over five years; in FY2004, the total DOE FreedomCAR and Fuel request is $272.1 million.

The funding request for the Fuel Cell Technology Program - which includes the development of polymer electrolyte membrane fuel cell technology in support of this initiative - increases from $57.5 million in our FY 2003 budget to $77.5 million in FY 2004. This increase will support, as noted above, a limited "learning" demonstration project for fuel cell vehicles and hydrogen infrastructure (with hydrogen sub-program) to integrate and validate component technologies; and an increase for fuel cell component research and development to reduce fuel cell cost.

The funding request for the Hydrogen Technology Program increases from $39.9 million in our FY2003 budget to $88.0 million in FY 2004 (plus $15.5 million in the Fossil Energy and Nuclear Energy programs, for a total of $103.5 million). This will be used to establish a national research effort on hydrogen storage; enhancing technology development for hydrogen production from renewables and distributed natural gas; accelerate codes and standards development; create a major hydrogen education effort; and validate hydrogen infrastructure technologies to support fuel cell vehicle test and evaluation.

These efforts support the President's Initiative, and will enable the development of hydrogen fuel cell vehicles for the showroom floor by 2020. Success of these programs will begin to eliminate the need for imported oil, while simultaneously reducing emissions and greenhouse gases from America's transportation fleet without affecting the freedom of personal mobility we demand.

Efficient Lighting Systems. The FY 2004 budget also will expand our research and development in Solid State Lighting, which represents a promising new approach to efficient lighting systems.

The lighting used in our homes and offices today is in many ways similar to the vacuum tubes that preceded solid state electronics. This comparatively inefficient lighting consumes about 7 quadrillion British thermal units of the Nation's energy each year and contributes to the peak energy demands that strain our electricity infrastructure. Advancing the technology and lowering the cost of organic and inorganic light emitting diodes will lead to more efficient, flexible and functional lighting technology in the future.

For FY 2004, we are proposing a $5 million investment to expand our Solid State Lighting research activities. Our Solid State Lighting research will create the technical foundation to revolutionize the energy efficiency, appearance, visual comfort, and quality of lighting products.

These efforts support the President's Initiative, and will enable the development of hydrogen fuel cell vehicles for the showroom floor by 2020. Success of these programs will begin to eliminate the need for imported oil, while simultaneously reducing emissions and greenhouse gases from America's transportation fleet without affecting the freedom of personal mobility we demand.

The Office of Fossil Energy

Overview. The Fossil Energy program is being realigned to focus virtually exclusively on supporting three of the President's top energy and environmental initiatives: Clear Skies, Climate Change, and Energy Security.

To be included in the FY 2004 budget, Fossil Energy programs must either (1) support the development of lower cost, more effective pollution control technologies or help diversify the nation's future sources of clean-burning natural gas to meet the President's Clear Skies goals; (2) expand the nation's technological options for reducing greenhouse gases either by increasing power plant efficiencies or by capturing and isolating these gases from the atmosphere; or (3) measurably add to the nation's energy security by providing a short-term emergency response (e.g., Strategic Petroleum Reserve) or a longer-term alternative to imported oil (e.g., hydrogen and methane hydrates).

The President's Coal Research Initiative. The President's Coal Research Initiative accounts for $320.5 million of the Fossil Energy research and development budget request. Since our budget testimony last year, the Department has made significant progress in implementing the initial stage of the President's $2 billion, 10-year commitment to a new generation of environmentally-clean coal technologies.

Our "first round" solicitation in the Clean Coal Power Initiative - a key piece of the President's clean coal commitment - attracted three dozen proposals for projects totaling more than $5 billion. On January 15, 2003, we announced the first winners of this competition - eight projects with a total value of more than $1.3 billion, more than one billion dollars of which would be provided by the private sector.

In FY 2004, we are requesting $130 million for the Clean Coal Power Initiative to fund joint government-industry research projects on new technologies that can enhance the reliability, efficiency, and environmental performance of coal-fired power generators.

To ensure that even more effective pollution controls continue to emerge in support of the President's Clear Skies Initiative, we are requesting $22.0 million for research into even cleaner and more affordable environmental innovations for existing plants.

Several of the recently-selected Clean Coal projects also expand the menu of options for meeting the President's Climate Change Initiative, primarily by boosting the efficiencies of power plants (meaning that less fuel is needed to generate electricity with a corresponding reduction in greenhouse gases). To position even more advanced, high efficiency power generating concepts for future development and testing, we are requesting $64.0 million to continue research into integrated gasification-combined cycle and a companion effort in high-performance, multi-fuel-capable turbines. A key aspect of these advanced power concepts - which will make up key modules of our "Vision 21" emission-free power plant of the future - is that they emit carbon dioxide in a way that makes the greenhouse gas easier to capture.

Carbon management will become an increasingly important element of our coal research program. Carbon sequestration - the capture and permanent storage of carbon dioxide - has emerged as one of our highest priorities in the Fossil Energy research program - a priority reflected in the proposed budget increase to $62.0 million in FY 2004 compared to an FY 2003 amended request of $44.0 million.

Carbon sequestration, if it can be proven practical, safe, and affordable, can dramatically enhance our long-term response to climate change concerns. It could offer the United States and other nations the option to reduce greenhouse gases that would not necessitate potentially disruptive and economically harmful changes in the way we produce, deliver, or use energy.

Beginning in FY 2004, one of the cornerstones of our carbon sequestration program will be a national network of regional partnerships. This Secretarial initiative will bring together the federal government, state agencies, universities, and private industry to begin determining which options for capturing and storing greenhouse gases are most practicable for specific areas of the country. We hope to start about four of these partnerships in FY 2004.

Among the research pathways we are pursuing in support of the Administration's Hydrogen Fuel Initiative will be innovative approaches for producing carbon-free hydrogen from coal by integrating coal-based hydrogen production technologies with permanent, stable carbon storage. Coal is a very attractive source of hydrogen through the coal gasification process. We have allocated $5.0 million for research into new methods for making hydrogen from coal.

To provide fundamental scientific knowledge that benefits all of our coal technology efforts, our FY 2004 budget also includes $37.5 million for advanced research in such areas as materials, coal utilization science, analytical efforts, and support for coal research at universities (including historically black and other minority institutions).

Other Power Systems Research and Development. We are also proposing $47 million for continued development of fuel cells with an emphasis on lower-cost technologies that can contribute to both Clear Skies emission reductions, particularly in distributed generation applications, and Climate Change goals by providing an ultra-high efficiency electricity generating component for tomorrow's power plants. Distributed power systems, such as fuel cells, also can contribute to the overall reliability of electricity supplies in the United States and help strengthen the security of our energy infrastructure.

Natural Gas Research. In response to the President's Clear Skies Initiative, the department is requesting $26.6 million for natural gas research. This clean-burning fuel will be integral to achieving the goals of Clear Skies.

Our natural gas research program, therefore, is directed primarily at research and development that can improve our utilization of this resource and provide sound science for policy decision-making. A particularly important aspect of this research will be to develop innovative ways to recover this resource from other sources such as hydrates, and to use natural gas to produce hydrogen.

The most significant new initiative in our Natural Gas Research program is the work we are proposing in hydrogen as part of the President's Hydrogen Fuel Initiative. We are requesting $6.5 million to study innovative methods to produce hydrogen from natural gas. We will ask industry, academia, and our national laboratories to submit new ideas on hydrogen production and related research. Since the byproduct of gas-to-hydrogen processes will likely be carbon dioxide, this effort will also include research on carbon capture and sequestration. This work will be closely coordinated with other efforts in the Office of Fossil Energy to capture and sequester carbon dioxide.

Over the long-term, the production of natural gas from hydrates could have major energy security implications. Hydrates - gas-bearing, ice-like formations in Alaska and offshore - contain more energy than all other fossil energy resources. The ability to develop hydrates as a natural gas source would be able to provide all our natural gas needs. Understanding hydrates can also improve our knowledge of the science of greenhouse gases and possible offer future mechanisms for sequestering carbon dioxide. For these reasons, we are maintaining a research program to study gas hydrates with a proposed funding level of $3.5 million.

Natural gas storage and transportation will also assume increasing significance in the United States as more and more power plants require consistent, year-round supplies of natural gas. Toward this end, we will initiate a nationwide, industry-led consortium that will examine ways to improve the reliability and efficiency of our nation's gas storage system and explore opportunities for liquid natural gas facility siting. We recognize that it has been decades since liquid natural gas has been a significant natural gas supply option. Through this new program, we are working to integrate thirty years of advances in technology, science and policy to secure the reliability of liquid natural gas storage and transport.

Oil Technology Development. The President's National Energy Policy calls attention to the continued need to strengthen our nation's energy security by promoting enhanced oil (and gas) recovery and improving oil (and gas) exploration technology through continued partnerships with public and private entities.

We also recognize that the federal oil technology research and development program must be more focused in order to achieve results and accomplish Presidential and departmental goals. Consequently, our FY 2004 budget request of $15.0 million reflects a reorientation of the program toward those areas where there is clearly a national benefit and the ability to contribute to the climate change and energy security goals.

The research and development activities directed towards the use of carbon dioxide injection to enhance the recovery of oil from existing fields will help achieve our climate change goals through an effective carbon sequestration method. Carbon dioxide injection is a proven enhanced oil recovery practice that prolongs the life of some mature fields, and the private sector has not applied this technique to its fullest potential due to insufficient supplies of economical carbon dioxide. A key component of carbon sequestration to be carried out in our proposed FY 2004 program will be to facilitate the greater use of this process by integrating it with carbon dioxide-captured and delivered from fossil fuel power plants.

We will also refocus much of our Oil Technology program on a new Domestic Resource Conservation effort that will target partnerships with industry and universities to sustain access to marginal wells and reservoirs. These aging fields account for 40 percent of our domestic production, yet contain billions of barrels of oil that might still be recovered with ever-improving technology. A high priority effort in FY 2004 will be to develop "micro-hole" technology. Rather than developing just another new drilling tool, the federal program will integrate "smart" drilling systems, advanced imaging, and enhanced recovery technologies into a complete exploration and production system. Micro-hole systems may offer one of our best opportunities for keeping marginal fields active because the smaller-diameter wells can significantly reduce exploration costs and make new drilling between existing wells ("infill" drilling) more affordable. This will enable us to maintain a consistent base of domestic oil production.

Other Fossil Energy R&D. Our budget request also includes $124.3million for other activities in our Fossil Energy program, including $92.8 million for headquarters and field office salaries, $3.0 million for plant and capital improvements, $9.8 million for environmental restoration, $6 million for federal matching funds for cooperative research and development projects at the University of North Dakota and the Western Research Institute, $2.8million for electricity and natural gas import/export responsibilities, and $10 million for advanced metallurgical research at our Albany Research Center. The increase in funding at the Albany Center (up from $5 million in FY 2003) reflects the Center's growing role in developing better materials for fuel cells and in studying new mineral carbonation concepts for carbon sequestration.

Conclusion

As the Committee is well aware, this testimony has not covered the enormous contributions science in our National Nuclear Security Administration (NNSA) is making to the DOE mission. From material research to high-performance computing, NNSA science is integrated into the full range of activities within my area of responsibility.

Mr. Chairman, I believe the Department's FY2004 budget submission meets the Nation's critical needs for energy, environmental and national security at a difficult time in our history. The committee has a central role in shaping the future of science and technology in the United States. The Department of Energy, which Secretary Abraham has said might well be called the Department of Energy and Science, hopes to join the members of the committee in working to strengthen American science.