[Extensions of Remarks]
[Pages E580-E581]
From the Congressional Record Online through the Government Publishing Office [www.gpo.gov]

INTRODUCTION OF THE NSF AUTHORIZATION ACT OF 2001

______

HON. EDDIE BERNICE JOHNSON

of texas

in the house of representatives

Wednesday, April 4, 2001

Ms. EDDIE BERNICE JOHNSON of Texas. Mr. Speaker, today, I am
introducing a bill to authorize funding for the National Science
Foundation (NSF) for the next four fiscal years. The bill provides for
increases of 15% for each year, which together with the 13%
appropriations increase for fiscal year 2001, will result in a doubling
of NSF's budget by the fourth year of the bill.
The need for this legislative proposal to provide a substantial
funding increase for NSF is beyond doubt, and the case supporting this
bill can be simply stated:
Federally supported basic research is fundamental to the nation's
economic health;
NSF plays a vital role in support of basic research and education
across all fields of science and engineering; and
There is ample evidence that the current level of federal research
investment is inadequate, particularly for the physical sciences,
mathematics, and engineering.
The connection between research funding and the strength of the
economy has been expounded by such diverse sources as former
presidential science advisor Allen Bromley, Federal Reserve Chairman
Alan Greenspan, former speaker of the House Newt Gingrich, and the
Hart-Rudman Commission on National Security.
Dr. Bromley, who was former President Bush's science advisor from
1989-1993, commented on the inadequacy of the research and development
portion of the Administration's FY 2002 funding request in a March 9
New York Times op-ed. He pointed out the potential damage of proposed
budget cuts for NSF, NASA and the Department of Energy agencies, which
he characterized as the three primary sources of ideas and personnel in
the high-tech economy. His key point was that the future budget
surpluses on which the large proposed tax cut depends are tied to
research investments made today. He said:

The proposed cuts to scientific research are a self-
defeating policy. Congress must increase the federal
investment in science. No science, no surplus. It's that
simple.

The importance of research to the economy was stressed by Federal
Reserve Chairman Greenspan in recent testimony before the House Budget
Committee also. In response to a question on the need for government
support for research, Greenspan responded,

On the issue of research, there is just no question that if
you're going to have technology as the base of your economy,
which we do, research is crucial. If we don't [enhance the
incentives to do research in this economy], we're going to
find that we are in a position where we may have awesome
technologies, but if you don't continuously nurture them,
they won't continue to exist.

The recent report of the U.S. Commission on National Security/21st
Century, known as the Hart-Rudman Commission, makes a strong case for
the importance of funding for basic research and technology
development. The Commission found that, ``it is from investment in
basic science that the most valuable long-run dividends are realized''
and ``[the federal] role remains not least because our basic and
applied research efforts in areas of critical national interest will
not be pursued by a civil sector that emphasizes short- to mid-term
return on investment.'' On the basis of its findings, the Commission
recommends a doubling of all federal funding for science and technology
research and development by 2010.
In testimony before the House Armed Services Committee on the Hart-
Rudman Commission report, former Speaker Gingrich stated that,

The revolution in science requires larger investments in
basic research; we are not getting the money today.

He also pointed out the importance of NSF's support for basic science
research.
I agree with Mr. Gingrich on the key role NSF plays in sustaining the
nation's research enterprise. NSF-supported researchers have collected
100 Nobel Prizes over the years. They have received recognition for
work in the fields of physics, chemistry, physiology and medicine, and
economics. In nearly every field of science and engineering are
examples of NSF-sponsored research that led to important discoveries
and applications:
NSF-funded research in atmospheric chemistry identified ozone
depletion over the Antarctic, or the ``ozone hole'' as it has come to
be known. In 1986, NSF researchers established chlorofluorocarbons as
the probable cause of the Antarctic ozone hole. Since CFCs are used in
many commercial applications, this discovery has driven a search for
benign substitutes and also led to regulation of CFC emissions.
When most people think of the Internet they mean the World Wide Web
and the Web Browsers, like Netscape, that allow them to find the
information they seek. The browser made the World Wide Web. The first
browser of note was Mosaic, and a student working at the National
Center for Supercomputing Applications at the University of Illinois
developed it. This is one of NSF's four original Supercomputing
Centers.
In industry, the acronym CAD/CAM brings to mind the best in design
and manufacturing techniques. NSF-funded research on solid modeling led
to the widespread use of Computer-Aided Design and Computer-Aided
Manufacturing. The keys to success were advances in the underlying
mathematics and in linking the academic and industrial leaders in the
field.
NSF's contributions are also manifest through the accomplishments of
scientists and engineers, who were trained under NSF awards. It is well
known that the great majority of the seminal work in developing such
technologies as cell phones, fiber optics, and computer assisted design
was performed by private industry--at labs like Corning, AT&T, and
Motorola. A recent NSF sponsored study has shown that many scientists
and engineers, who went to graduate school on NSF fellowships and
research assistantships, often played important roles in the
development of these and other technologies. In a number of cases, they
became the entrepreneurs who created new firms and markets. To use the
words of the authors of the study--``NSF emerges consistently as a
major--often the major, source of support for education and training of
the Ph.D. scientists and engineers who went on to make major
contributions. . . .''.
The resources NSF provides for support of research and education are
relatively small, but the impact is great. The agency expends only 3.8%
of federal R&D funds, but provides 23% of basic research funding at
academic institutions. For specific research areas, the NSF role at
universities is even larger: it funds 36% of research in the physical
sciences, 49% in the environmental sciences, 50% in engineering, 72% in
mathematics, and 78% in computer science. NSF research awards and
direct research fellowships help train over 24,000 graduate students
each year, the future scientists and engineers essential to fuel our
high-tech economy.
Furthermore, NSF programs help to improve science education for all
students and to prepare them for citizenship in a world increasingly
dominated by technology. Today we continue to have manpower shortages
in many high technology fields. The ideal way to alleviate the
shortages is by ensuring that children of all races and both genders
receive the basic grounding in science and mathematics that will
prepare them to pursue careers as scientists, engineers and
technologists. We cannot allow inadequate funding to cripple NSF's
efforts in this area.
There is really no debate on whether support of basic research is an
appropriate role of the federal government. The basic economic argument
is well understood. Industry will underinvest in basic research because
individual companies cannot capture the full benefits of advances in
fundamental knowledge that come from funding basic research.
The question, rather, is what ought to be the level of the federal
research investment? The bill I am introducing takes the position that
it is too low, particularly for basic research in the fields for which
NSF is a major funding agency: the physical sciences, mathematics, and
engineering.
The National Research Council's Board on Science, Technology and
Economic Policy analyzed federal funding data for FY 1993 through FY
1997. They found that support, in constant dollars, for chemical
engineering had declined by 13%, electrical engineering by 36%,
mechanical engineering by 50%, physics by 29%, chemistry by 9%, and
mathematics by 6%. Even including the substantial increases for
research for biomedical sciences

[[Page E581]]

during this period, total federal research funding for all fields of
science and engineering declined by about 1%.
Inadequacies in the size of NSF's budget are evident from the fact
that the agency currently funds less than a third of the research
applications it receives and about half of those judged to be of high
quality. Even when an applicant receives a NSF award, it is usually
suboptimal and perhaps half the amount of a NIH award. The current
situation leaves researchers in NSF-funded fields scrambling for funds
and spending too much of their time chasing limited funding rather than
in the laboratory or mentoring students.
The NSF authorization bill I am introducing will provide increases of
15% per year for fiscal years 2002 through 2004. The bill will result
in a NSF budget of $7.7 billion by the final year. The increases
provided will allow NSF to go forward with substantial new research
initiatives in the mathematical sciences and the social and behavioral
sciences and to continue ongoing initiatives in information technology,
biodiversity, and nanotechnology. Moreover, the budget growth will
allow NSF to--
Increase average grant size and duration;
Fund national research facilities for the earth and atmospheric
sciences, astronomy, and the computational and information sciences;
and
Support large scientific instruments at colleges and universities.
Finally, the increases will support expansion of NSF's science
education programs. Of particular importance will be increased efforts
to improve the skills and content knowledge of K-12 science and math
teachers and to increase participation in science and engineering by
traditionally underrepresented groups. The increases will also expand
education research programs, including quantifying the most effective
uses of educational technology and strengthening efforts to assess
education programs to determine and disseminate information about what
methods and approaches are most effective in improving student
performance in science and math.
The Coalition for National Science Funding (CNSF), a group of eighty
scientific, engineering, and professional societies, universities, and
corporations has called for providing no less than $5.1 billion, a 15%
increase, for the NSF in FY 2002 as the next step in doubling the NSF
budget. CNSF has stated that:

Our national knowledge base in the sciences, mathematics,
and engineering is increasingly important to broad economic
and social interests. Doubling the NSF budget by 2006 will
fund the crucial investments that the agency makes in key
components of this vital knowledge base.

Mr. Speaker, the NSF Authorization Act of 2001 implements the
recommendations of CNSF. I hope all my colleagues will join me in
ensuring that NSF has the necessary resources to carry out its
essential role in support of scientific and engineering research and
education by becoming cosponsors and supporters of this authorization
bill.

____________________