Summary of FY2001 Budget Request to Congress - National Science Foundation

 

MATHEMATICAL AND PHYSICAL SCIENCES $881,160,000

The FY 2001 Budget Request for the Mathematical and Physical Sciences Activity is $881.16 million, an increase of $123.56 million, or 16.3 percent, over the FY 2000 Current Plan of $757.60 million.

(Millions of Dollars)

 

FY 1999
Actual

FY 2000
Plan

FY 2001
Request

Change

Amount

Percent

Astronomical Sciences

118.54

122.87

139.70

16.83

13.7%

Chemistry

135.34

138.99

161.99

23.00

16.5%

Materials Research

186.37

191.16

220.61

29.45

15.4%

Mathematical Sciences

100.75

106.29

130.21

23.92

22.5%

Physics

162.74

168.35

198.65

30.30

18.0%

Multidisciplinary Activities

29.91

29.94

30.00

0.06

0.2%

Total, MPS

$733.65

$757.60

$881.16

$123.56

16.3%

The Mathematical and Physical Sciences Activity (MPS) supports a strong and diverse portfolio of research and education in astronomical sciences, chemistry, materials research, mathematical sciences and physics. The purpose of this work is threefold: to deepen our understanding of the physical universe; to use this understanding in service to society; and to prepare the next generation of scientists who are essential for continued progress. The mathematical and physical sciences underpin many other scientific endeavors and serve as the training ground for at least half of all doctoral scientists now employed in U.S. industry. The MPS Activity supports areas of inquiry that are critical for long-term U.S. economic strength and security, providing a substantial portion of federal funding for fundamental research at academic institutions in these areas, and in some subfields provides for most of the federal investment.

The new opportunities are many. Research at the atomic level will result in a period of discovery that could be termed a "molecular revolution." The study of complex chemical and physical systems offers critical insights into climate change and other natural phenomena. Biological systems can be understood and controlled via powerful mathematical and physical techniques, such as the creation of algorithms critical for drug design and for the development of biopolymers, gels, and other biomolecular materials. New tools critical to scientific progress - from advanced magnets, to novel sensors, to quantum computers, to more powerful telescopes - are being developed and refined, and will make possible the understanding of physical phenomena at a much more profound level. Essential to achieving these goals is the development of new mathematical tools and algorithms for modeling and simulation of physical and biological phenomena.

MPS places a high priority on multidisciplinary work and on partnerships. The Multidisciplinary Activities Subactivity is designed to catalyze efforts in emerging areas of research and education at disciplinary boundaries. By fostering closer connections with other federal agencies, state governments and industry, MPS investigators can enhance the impact of their efforts and increase the return on NSF investments.

International partnerships are critical to progress, both intellectually and financially, especially in the areas of astronomy, physics, and materials research, all of which require the use of large facilities. An example is the strong international cooperation that the Astronomy Subactivity has generated in support of the Gemini Observatories. Another is the collaboration with the Department of Energy's (DOE) Office of Science and with the European Organization for Nuclear Research (CERN) that the Physics Subactivity has pursued toward the development of detectors for the Large Hadron Collider (LHC).

World leadership in science is a critical objective for the Foundation. Receipt of Nobel Prizes by MPS-supported physical scientists and Fields Medals by MPS-supported mathematical scientists is a strong indicator of the long-term importance of MPS research. The 1999 Nobel Prize in Chemistry was awarded to Ahmed H. Zewail of the California Institute of Technology for his studies of the transition states of fundamental chemical reactions using ultrashort laser flashes, on the time-scale in which the reactions occur (femtosecond spectroscopy). Zewail's work shows that it is possible with rapid laser techniques to see how atoms in a molecule move during a chemical reaction. Professor Zewail's contributions have brought about a revolution in chemistry and adjacent sciences, allowing us to understand and predict important reactions. Professor Zewail's work has been supported by MPS for twenty years.

People are NSF's most important product. At NSF, placing research and learning hand in hand is our highest priority, and the people involved in our projects represent both the focus of our investments and the most important products of them. Across its programs, MPS provides support for approximately 21,300 people, including teachers, students, researchers, post-doctorates, and trainees. Support for programs specifically addressing NSF's Strategic Goal of "People -- A diverse, internationally competitive and globally-engaged workforce of scientists, engineers and well-prepared citizens" totals more than $106 million in FY 2001, an increase of 19.0 percent over FY 2000. Moreover, about 45 percent of the funding for research grants -- an amount approaching $260.0 million in FY 2001-- provides support for researchers and students, including almost 12,400 post-doctorates, trainees, and graduate and undergraduate students.

In FY 2001, MPS will support research and education efforts related to broad, Foundation-wide initiatives in Information Technology Research, Nanoscale Science and Engineering, and 21 st Century Workforce.

Information Technology Research (ITR)

MPS contributes very heavily in all of its Subactivities to the national effort in large-scale computational science. This work has brought dramatically improved understanding of fundamental scientific phenomena in astronomy, chemistry, physics, and materials research. The computational sciences have also provided increasingly sophisticated techniques for gathering, manipulating, storing and analyzing experimental data. MPS-supported research may even bring about entirely new ways of computing, for example, quantum computing, by which the rules of quantum mechanics may be exploited to expand enormously our ability to store and process information. In addition, the mathematical sciences make essential contributions to fundamentals of computer science itself, as well as providing the calculational algorithms, imaging methods, and cryptographic techniques needed across an enormous spectrum of activity in science, engineering, national defense, and business. The ITR initiative will benefit substantially from the contributions of work supported by MPS.

MPS support for the NSF initiative in Information Technology Research (ITR) will total $45.10 million in FY 2001. This investment will focus on specific thrusts that include:

  • Essential contributions to algorithm development, statistical analysis, optimization theory, network design, the physics of information, understanding the limits to computation, and the fundamentals of quantum and optical computing.

  • The development of ultra-miniature chemical switches, gates, new realizations of electronics , nanodevices, and totally new possibilities such as quantum, biological and optical computers.

  • Advanced computational methods resulting, for example, in the design of more effective drugs and specialized materials.

These fundamental computational challenges in MPS have and will continue to push the state-of-the-art of software and hardware developments in many areas of information technology. Expanding these capabilities will require additional investment in:

  • Advanced computational hardware and software development;

  • The ability to store and quickly transmit very large databases;

  • Enabling remote access and control of experimental facilities such as accelerators, telescopes and large databases; and

  • Educating the workforce using the power of the World Wide Web.

Nanoscale Science and Engineering

In FY 2001, the MPS request includes $111.41 million for nanoscale science and engineering, an increase of $50.41 million over the FY 2000 Current Plan. This increase includes $10.0 million for activities in the Quantum Realm - where the laws of quantum mechanics play a decisive role.

MPS has been a leader in fostering the exciting emergence of nanoscale science and engineering over many years. MPS grantees have contributed significantly to many of the exciting advances made over the past year, which illustrate both the scientific fascination and the technological potential of nanoscale phenomena and structures. Examples include: the demonstration of controlled molecular switching by scientists at the University of California, Los Angeles and Hewlett Packard Corporation; the development of 'molecular tweezers' by researchers at Harvard University, and 'optical tweezers' for molecular control by researchers at AT&T, Harvard University, and Stanford University; and advances made by a research team at the University of California, Santa Barbara in demonstrating quantum coherence in spin-electronic magnetic materials.

In FY 2001, MPS will play a major role in the NSF's contribution to the interagency National Nanotechnology Initiative in the following areas: Nanoscale Structures and Quantum Control; Multi-scale, Multi-phenomena Modeling and Simulation at the Nanoscale; and Nanostructures in the Environment. MPS is also expected to contribute in the areas of Biosystems at the Nanoscale and Device and System Architecture. An integral component of this initiative includes the preparation and training of the future workforce in this critical field.

21 st Century Workforce

MPS support will increase $300,000, for a total of $3.30 million in FY 2001 for this initiative. This includes continued support for the NSF-wide program for Graduate Teaching Fellows in K-12 Education; for the Interagency Education Research Initiative program, a collaborative program with the Department of Education; and the Distinguished Teaching Scholars program.

STRATEGIC GOALS

MPS's support for ongoing and new activities contributes to NSF efforts to achieve its strategic goals, as well as to the administration and management activities necessary to achieve those goals. MPS's investment in NSF's strategic goals is as follows:

(Millions of Dollars)

 

FY 2000
Current Plan

FY 2001
Request

Percent
Change

Ideas

472.59

578.63

22.4%

People

89.12

106.03

19.0%

Tools

192.20

190.08

-1.1%

Administration & Management

3.69

6.42

74.0%

Total, MPS

$757.60

$881.16

16.3%

Ideas

MPS supports research activities across a very broad spectrum - from studies of the origin of the universe to investigations of the inner structure of matter, from understanding the dynamic nature of chemical reactions in real time to the design, from fundamental principles of materials with new properties and from the proof of centuries old mathematical theorems to the development of new and efficient computational techniques. Support for discovery at and across the frontier of science and engineering and connections to its use in the service of society account for about two-thirds of the funding in the MPS Activity. Awards include support of single investigators, centers or groups of investigators, with the particular mode of support chosen to meet the needs of the research.

Funding for fundamental research will increase in FY 2001 by $106.04 million, to a total of $578.63 million. Interdisciplinary research is becoming an increasingly important aspect of progress in all of the sciences. In FY 2001, funding will focus on the following areas characterizing a large portion of the MPS portfolio:

  • Mathematics: In FY 2001, mathematics will receive high priority within MPS. The mathematical sciences continue to play essential roles in both independent discovery and in support of other fields of research; indeed, mathematics is the foundation and vital backbone of both today's and tomorrow's science, engineering, computation, and technology. The mathematical sciences-linked with science and engineering-the computation, visualization, algorithms, models, and theoretical tools of discovery. Support for this effort will increase in FY 2001 by an estimated $18.02 million.

  • Origins of the Universe: Research in this area seeks to answer some of the most fundamental questions of all: How did the universe begin? How did matter, planets, stars, and the galaxy form? Did life exist elsewhere in the universe? Does it now? How did life originate on earth? We still do not know exactly how the chemical elements form or how galaxies, stars, and planetary systems are born and evolve. We do not completely understand the Sun's effects on processes here on Earth. These critical questions require many complementary contributions from astrophysics, particle physics, nuclear physics, exobiology, and chemistry. Ground-based telescopes, such as the Gemini Observatories currently under construction, and accelerators, such as the Large Hadron Collider (LHC), the National Superconducting Cyclotron Laboratory (NSCL), and the Laser Interferometer Gravity-Wave Observatory (LIGO) will all contribute to finding the answers to these questions, as do companion efforts in theoretical physics and chemistry. It is estimated that increased support of $20.0 million will be provided in FY 2001.

  • The Quantum Realm: To capitalize on recent discoveries and technological advances, support for study of the quantum realm-the laws of quantum mechanics play a decisive role-increase in FY 2001. Mathematicians and physicists working together are finding important links between quantum theory and fundamental mathematics that have been beneficial to both fields. This area of research covers diverse topics such as the fundamental makeup of matter, the nature of the chemical reactions that control our environment, and the development of new materials. On the atomic and molecular scale, the use of very precise lasers now allows us to slow, trap, and manipulate single atoms and to study chemical reactions in real time. Fundamental research on nanostructures such as quantum dots is providing insight into "artificial atoms" and leading to new approaches to the fabrication of electronic and optical devices. Increased support in FY 2001 for the study of topics in this area are estimated at $10.0 million.

    Information technology, encompassing information storage, transmission, manipulation, and utilization, will become one of the defining features of the 21 st century. As physical systems used to implement information technology become smaller, their behavior is increasingly determined by quantum, not classical, principles. Among the most exciting of recent developments is the demonstration of nonclassical transfer of quantum information, a crucial step if the exploitation of the tremendous potential associated with quantum information is to become a reality.

  • Molecular Connections: The importance of understanding phenomena at the molecular level, including studies of the environment, continues to grow. MPS will give high priority to the design, synthesis and characterization of nanostructures (associations of molecules smaller than 50 nanometers) and will participate in Foundation-wide initiative of nanoscale science and engineering. Past activities in this area have, for example, resulted in the synthesis of nanoscale molecular structures that mimic plant photosynthetic systems in harvesting light, the development of artificial nanochannel membranes that can act as molecular catalysts, and new techniques for direct-write nanolithography based on atomic force microscopy. Molecular connections are important in studies of the environment as well. The complexity of the underlying systems and processes often requires multi-disciplinary programs that bridge the interfaces between MPS and other disciplines, including engineering, geology, and biology. MPS will continue to play a leadership role in environmental studies within the Foundation. Increased support for molecular research in FY 2001 will be approximately $5 million.

In FY 2001, MPS will continue to implement efforts to address the Foundation-wide concern about grant sizes by increasing the average size and duration of awards. MPS will also continue to pay attention to the percentage of competitive research grants for new investigators.

MPS also supports a number of centers:

(Millions of Dollars)

 

FY 2000
Estimate

FY 2001
Estimate

Percent
Change

Science and Technology Centers 1

6.49

5.19

-20.0%

Materials Research Science & Engineering Centers

51.79

57.79

11.6%

Physics Frontiers Centers

0.00

5.00

NA

Mathematical Sciences Research Institutes

7.60

8.52

12.1%

Chemistry Centers

10.24

10.99

7.3%

Total, MPS

$76.12

$87.49

14.9%

1 The reduction of support for STCs reflects the planned phase-out of the second class in FY 2000 and FY 2001.

Center-based research brings together scientists from diverse disciplines to work on complex problems, often in partnerships with other academic institutions, national laboratories, and industry. Centers are strongly committed to the integration of research and education, at levels from pre-college to postdoctoral, and they maintain sophisticated experimental facilities generally accessible to a broad range of users.

MPS currently supports three Science and Technology Centers (STC), 28 Materials Research Science and Engineering Centers (MRSEC); four Chemistry Centers; and three Mathematical Sciences Research Institutes (MSRI). The research activities of the STCs include electronic materials, ultrafast optical science, and advanced display materials. In the MRSECs, researchers from many disciplines including engineering, biology and the mathematical and physical sciences address fundamental problems of intellectual and technological importance encompassing a wide range of materials and phenomena. The Chemistry Centers and the Mathematical Sciences Research Institutes address critical and emerging themes focused in these fundamental areas.

Interdisciplinary teams at a number of MRSECs and STCs are working in close partnership with teachers and educators to bring materials science alive for pre-college students in a variety of programs. For example, the Garcia Center for Polymers at Engineered Interfaces (a MRSEC at SUNY Stony Brook) hosts an open house each year at Queens College, a participating institution in the Center. The event aims to pique students' curiosity about careers in science and engineering. This year nearly 400 high school students and their teachers engaged in a one-day research experience on modern polymer science and technology. Also this year, seven high school students sponsored by the Garcia Center are among the national semifinalists for the prestigious Intel Science Talent Search competition. Overall, the MRSECs supported K-12 science and engineering outreach activities that reached more than 300 teachers and 11,000 students in FY 1999. In addition, the Materials World Modules program developed with NSF support through the MRSEC at Northwestern University has been adopted by more than 15 school districts across the country and now reaches about 100,000 pre-college students and their teachers.

In FY 2001, support for centers will include:

  • Three Physics Frontier Centers will be established through open competition for a total of $5.0 million. These centers will provide critical resources and needed infrastructure to exceptionally promising new areas of physics.

  • An increase of $6.0 million, to a total of $57.79 million, will support the establishment of up to four new MRSECs through open competition. These Centers will undertake interdisciplinary materials research and education in critical areas such as nanoscale science and engineering, Information Technology Research, and the interface between materials and biology.

  • An increase of $1.67 million will support Chemistry centers in advanced molecular characterization and help strengthen support for the Mathematical Sciences Research Institutes.

People

The preparation of a diverse, broadly trained, internationally capable workforce for the 21 st century is a primary focus for MPS activities. This workforce will be responsible for bringing forth the ideas and discoveries that expand the frontiers of understanding and for developing and using new tools that enable discovery and learning in the next millennium. To accomplish this and to increase the understanding of science by the nation's citizens, MPS will increase its FY 2001 investment in People by $16.91 million, to a total of $106.03 million, or 19.0 percent. These investments will support innovations in education and training from K-12 through the postdoctoral and senior levels. Funding identified in the table below includes only dedicated education and training activities and excludes the much more extensive education and training activities supported through research awards and those taking place at centers and facilities.

MPS activities play a key role in integrating science and education at the graduate and undergraduate levels, and in helping people of all ages experience the thrill of "discovering science." For example, nearly 200 REU Sites are supported by MPS which expose almost 2,000 undergraduate students to the excitement of discovery at the frontiers of mathematics and science. In addition to supporting REU sites, MPS also sponsors many outreach programs at its centers and facilities that help bring the excitement of current scientific discovery to the public.

(Millions of Dollars)

 

FY 2000
Estimate

FY 2001
Estimate

Percent
Change

K-12

4.38

7.85

79.2%

Undergraduate

21.57

26.48

22.8%

Graduate/Professional

63.07

70.50

11.8%

Other

0.10

1.20

1100.0%

Total, MPS

$89.12

$106.03

19.0%

The FY 2001 increase for People in MPS totals $16.91 million:

  • Web-based education and teacher enhancement activities at the K-12 level will support cooperative interactions with cutting edge MPS-supported research sites. MPS support will include K-12 teachers' experiences in discovery-based learning, in conjunction with MPS REU Sites, and efforts to increase diversification among participants in science early in the school experience. In cooperation with the Education and Human Resources Activity, MPS will support workshops that identify best educational practices at the K-12 level and make these models widely available to the community.

  • Investments in undergraduate education activities will increase by $4.91 million, to a total of $26.48 million, to provide students with broadened curriculum content and expanded laboratory experiences; begin to reform education in materials research and physics; and support the development and educational utilization of digital libraries and other technological innovations. Through MPS-supported regional sites (e.g., Regional Sites for Educators in Chemistry), faculty from 2 and 4-year institutions will be provided with opportunities to carry out cutting-edge research in collaboration with colleagues from research-intensive host institutions.

  • At the graduate and professional level, MPS will increase its investment by $7.43 million, to a total of $70.50 million. This increment will enable continued support of the Foundation-wide multidisciplinary Integrative Graduate Education and Research Traineeship (IGERT) program and increased support of the Vertical Integration of Research and Education in the Mathematical Sciences (VIGRE) program. These traineeship programs are significantly broadening graduate education, increasing diversity, and are expected to lead to a shortening of the time to the Ph.D. degree, as well as produce graduates who are prepared for a wider spectrum of career opportunities. New experiments in graduate education will be supported, including coalitions with professional societies, that will encourage and reward programmatic innovation in disciplinary departments, particularly those designed to recruit and retain graduate students from traditionally underrepresented groups. Also, included is MPS support (+$900,000) of international postdoctoral research fellowships to enable young scientists to carry out research at the leading facilities and laboratories throughout the world. Such experiences provide young scientists with an increasingly important international dimension to their professional development and are critically important to those whose research is strongly coupled to the unique capabilities afforded by these environments.

  • Informal science education will increase by $1.10 million to support public access to MPS-supported cutting edge research in individual investigator laboratories, institutes, centers, and facilities through linkages to museums and science centers, including visitors' centers at research facilities such as the Laser Interferometer Gravitational Wave Observatory (LIGO).

Tools

Today we are in an era of exploding scientific opportunity enabled by numerous revolutions in our ability to create new tools for science. These devices have allowed a stunning view into nature that has captured the imagination of the world - from the far reaches of the universe and the beginnings of time to the fundamental makeup of matter and the workings of life. As a result, these new tools are spread across the breadth of science and engineering. While instruments and their supporting infrastructure are becoming more costly and complex, the scientific problems we face today involve phenomena at or beyond the limits of our measurement capabilities. These problems can only be studied and solved with new generations of powerful tools.

Continued advances and leadership in astronomy, physics, and many areas of materials science depend critically on the availability of state-of-the-art user facilities to enable research and education at the cutting edge of science for large communities of university faculty and students. This requires investments for ongoing operations, maintenance, and periodic upgrades to the facilities as well as to ancillary instrumentation that may be needed to provide continued forefront research opportunities to users.

Research and development (R&D) towards new capabilities at existing facilities, and for new facilities to meet the needs of the MPS disciplines is carried out with support provided through basic disciplinary research. Activities include: R&D towards the next generation LIGO detectors, future accelerators at the energy frontier, enhanced neutron scattering capabilities at the National Institute of Standards and Technology (NIST) and the Spallation Neutron Source (SNS), high magnetic field capabilities at the National High Magnetic Field Laboratory (NHMFL), and new capabilities at the national astronomy centers. In addition, MPS, jointly with the Department of Energy, manages the U.S. Large Hadron Collider (LHC) detector construction project. For additional information on the LHC, see the Major Research Equipment Account.

MPS investments in Tools include:

(Millions of Dollars)

 

FY 2000
Estimate

FY 2001
Estimate

Percent
Change

Laser Interferometer Gravitational Wave Observatory

21.10

19.10

-9.5%

Gemini Observatories

8.05

8.65

7.5%

Cornell Electron Storage Ring

19.50

19.50

0.0%

MSU National Superconducting Cyclotron Laboratory

14.53

10.78

-25.8%

National High Magnetic Field Laboratory

17.50

17.50

0.0%

National Astronomy Centers

71.26

71.26

0.0%

Research Resources 1

21.67

24.67

13.8%

Other Facilities 2

18.59

18.62

0.2%

Total, MPS

$192.20

$190.08

-1.1%

1 Includes instrumentation programs in Astronomical Sciences, Chemistry, Materials Research, and Mathematical Sciences Subactivities.
2 Includes the Indiana University Cyclotron Facility, Wisconsin Synchrotron Radiation Center, Cornell High-Energy Synchrotron Source, NIST Neutron Scattering Facility, National Nanofabrication Users Network, National Center for Atmospheric Research, Digital Library, and the National High Field Mass Spectrometry Center.

 

In FY 2001, facilities supported through Tools includes the following:

  • The Laser Interferometer Gravitational Wave Observatory (LIGO): A planned decrease of $2.0 million, to a total of $19.10 million, for operation of the two LIGO sites in Hanford, Washington and Livingston Parish, Louisiana. LIGO detector installation will be completed in FY 2000 and the facility engaged fully in commissioning activities. The funds will provide for operating and research staff and for infrastructure as commissioning activities move towards initial coincidence observations between the two sites in FY 2001. Normal science running is planned to start in FY 2002. Construction funding provided through the Major Research Equipment account was completed in FY 1998. MPS will provide oversight of the project as it moves to full installation, commissioning, and operation.

  • Gemini Observatories: An increase of $600,000 to a total of $8.65 million, for the Gemini Observatories to support research at the observatory sites. The northern observatory on Mauna Kea achieved first light in December 1998 and is expected to be ready for operational handover in June 2000. First light at the southern site observatory at Cerro Pachon, Chile is scheduled for FY 2000. Astronomical observations for the northern site are expected to commence in June 2000. Gemini North (followed shortly by Gemini South) will offer world-class and unique opportunities to the scientific community both in the infrared optimization of the telescope and in the use of adaptive optics.

  • Cornell Electron Storage Ring (CESR): Funding is maintained at $19.50 million for CESR. This funding includes support for effective operations of the facility, including its strong accelerator physics program, following completion of the CESR upgrade. CESR serves a broad user community and continues to be a world-leading center for study of the B-meson and its relation to the electro-weak force and to understanding the matter-antimatter asymmetry in the universe.

  • The Michigan State University's National Superconducting Cyclotron Laboratory (MSU NSCL): A decrease of $3.75 million, to a total of $10.78 million, is in accordance with the construction schedule for the radioactive ion beam upgrade project, which will be completed at the end of FY 2001. The upgrade will provide important research opportunities for hundreds of users of the NSCL, with particular emphasis on astrophysics, a continued high priority within nuclear science and within physics overall.

  • The National High Magnetic Field Laboratory (NHMFL): Funding for operations of the NHMFL will be maintained at $17.50 million. The NHMFL provides world leadership in high magnetic field capability, supporting the research needs of hundreds of researchers across a broad spectrum of science and technology. The NHMFL recently tested the world's highest continuous field magnet for use in studies of the structure of matter under extreme conditions, including possible new phases of matter. The NHMFL is operated by Florida State University, the University of Florida, and the Los Alamos National Laboratory, and is funded in partnership by NSF, the Department of Energy, and the State of Florida.

  • The National Astronomy Centers: Funding for operation of the three national astronomy centers is maintained at $71.26 million. These centers provide observing capability in the radio and optical/infrared regimes of the spectrum for all scientists on the basis of scientific merit: NOAO maintains observing capabilities at optical/infrared wavelengths in both the northern and southern hemispheres; the Very Long Baseline Array (VLBA) and the Very Large Array (VLA) of NRAO provide very high resolution radio images of celestial objects; and the capabilities of NAIC have been significantly enhanced through upgrade of the feeds and installation of ground screens.

  • The Indiana University Cyclotron Facility (IUCF): Funding is continued at $6.50 million for support of research and operations. The laboratory is operating under an agreement whereby its Cooler facility will complete a set of critical experiments in the study of few-nucleon systems, and then be phased out to make room for new opportunities across the Physics Subactivity programs. IUCF is scheduled for closure in FY 2002.

  • Research Resources: An increase of $3.0 million for a total of $24.67 million is planned to enhance MPS investment in shared instrumentation for university departments, new instrumentation development, and for facility-related instrument development and operation.

Administration and Management

Administration and Management provides for administrative activities necessary to enable NSF to achieve its strategic goals. This includes the cost of Intergovernmental Personnel Act appointments, contractors performing administrative functions and, in FY 2001, travel by staff in the program offices.

BUDGET PRESENTATION

NSF has previously organized its budget presentation around four key program functions - Research Project Support, Research Facilities, Education and Training, and Administration and Management. In order to link the FY 2001 Budget Request to the NSF Strategic Plan, we have organized the FY 2001 Budget Request around the strategic outcome goals of Ideas, People and Tools, as well as the Administration and Management activities necessary to achieve these goals.

The table below provides an FY 2001 crosswalk for MPS between funding for the strategic goals and the key program functions.

(Millions of Dollars)

 

Ideas

People

Tools

A&M

Total,
MPS

Research Project Support

578.63

53.16

25.94

 

$657.73

Facilities

 

 

163.14

 

$163.14

Education & Training

 

52.87

1.00

 

$53.87

Administration & Management

 

 

 

6.42

$6.42

Total, MPS

$578.63

$106.03

$190.08

$6.42

$881.16

Number of People involved in MPS Activities


 

FY 1999
Actual

FY 2000
Estimate

FY 2001
Estimate

Senior Researchers

5,501

5,470

6,100

Other Professionals

1,633

1,760

1,900

Post-Doctorates

1,885

1,950

2,190

Graduate Students

5,605

5,450

6,200

Undergraduate Students

3,834

3,840

4,000

K-12 Students

560

570

630

K-12 Teachers

250

290

300

Total Number of People

19,268

19,330

21,320

MPS Funding Profile


 

FY 1999
Actual

FY 2000
Estimate

FY 2001
Estimate

Number of Requests for Funding

8,172

8,250

8,700

Dollars Requested (in thousands)

$3,127,340

$3,700,000

$3,900,000

Total Number of Awards

4,235

4,225

4,300

Statistics for Competitive Awards

 

 

 

Number

1,891

1,810

1,920

Funding Rate

37%

37%

37%

Median Annualized Award Size 1

$77,000

$77,000

$81,000

Average Annualized Award Size 1

$94,000

$96,000

$110,000

Average Award Duration, in years 1

2.9

3.0

3.0

1 Statistics for award size and duration are for research grants only.

 

 

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