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National Nanotechnology Investment
|
NSF Directorate |
FY 2002 |
FY 2003 |
FY 2004 |
---|---|---|---|
Biological Sciences |
2.3 |
3.0 |
5.0 |
Computer and Info. Sci. and Eng. |
10.2
|
11.1 |
15.1 |
Engineering |
86.3 |
94.4 |
106.9 |
Geosciences |
6.8 |
7.5 |
7.9 |
Mathematical and Physical Sci. |
93.1 |
103.9 |
110.4 |
Social and Behavioral Sci |
0.0 |
1.1 |
1.5 |
Education and Human Resources |
0.0 |
0.2 |
0.2 |
Others |
5.0 |
--- |
--- |
Total, NSF Nanoscale Sci. and Eng. |
203.7 |
221.2 |
249.0 |
Note: Totals may not add due to rounding.
The investment will expand a wide range of research and education activities in this priority area, including approximately 20 nanotechnology research and education centers, which focus on electronics, biology, optoelectronics, advanced materials and engineering. The National Nanotechnology Infrastructure Network will be established with first year funding of about $14 million.
Long-term objectives include laying a foundation of fundamental research for NNI Grand Challenges; ensuring that U.S. institutions will have access to a full range of nano-facilities; enabling access to nanotechnology education for students in U.S. colleges and universities; and catalyzing the creation of new commercial markets that depend on three-dimensional nanostructures. This should result in the development of completely new technologies that contribute to improvements in health, advanced agriculture, conservation of materials and energy, and sustainability of the environment. This investment will be expanded in FY 2004 to develop and strengthen critical fields and to establish the science and engineering infrastructure and workforce needed to exploit the opportunities presented by these new capabilities. Converging technologies from the nanoscale, with a focus on improving human performance, will be included. In addition to single-investigator research, support will be focused on interdisciplinary research and education teams, national science and engineering centers, exploratory research and education projects, and education and training.
NSF's planned investment for Nanoscale Science and Engineering in FY
2004 will have five programmatic foci: 1) Fundamental Research and Education,
$151.7 million; 2) Grand Challenges, approximately $10.1 million; 3) Centers
and Networks of Excellence, approximately $45.9 million; 4) Research Infrastructure,
approximately $28.70 million; and 5) Societal and Educational Implications
of Science and Technology Advances, approximately $12.6 million. The education
and training activities will be extended to undergraduate and K-12 education.
The National Nanotechnology Infrastructure Network (NNIN) for user facilities,
development of new instrumentation, and training will be established with
an initial funding of $14 million per year.
TThe FY 2004 request is $222 million, $20 million less than FY 2003 (see Table I-10). The principal DOD participants in the NNI are the Directorate for Defense Research and Engineering (DDR&E), the Defense Advanced Research Projects Agency (DARPA), the Air Force, the Army and the Navy. While the NNI is a fundamental science (DOD's "6.1" funding category) based initiative, one of the principal NNI goals is to transition science discovery into new technology. The DOD structures its S&T investment into basic research ("6.1"), applied research ("6.2") and advanced technology development ("6.3"); the latter two focus on transitioning science discovery into innovative technology. In FY 2002, DOD began tracking and encouraging the transitions into these applied programs.
The University Research Initiative program in FY 2001 added 16 nanoscience projects as part of a Defense University Research Initiative on Nanotechnology (DURINT) competition and another five nanoscience projects under the traditional competition; the projects carry a five-year commitment in FY 2004. DARPA would have a significant contribution in the nanoscience/nanotechnology investment portfolio in FY 2004. The Air Force is looking to increase its investment in nanoscience. It is anticipated that its basic research activities will expand research in nanocomposites and hybrid polymer-inorganic nanocomposites; self-assembly and nanoscale processing for the realization of 3-D optical and electronic circuitry; highly efficient space solar cells; nanoenergetics-understanding the factors that control reactivity and energy release in nanostructured systems; nanostructures for highly selective sensors and catalysts; as well as nanoelectronics, nanomagnetics and nanophotonics, nanostructured coatings, ceramics and metals. The Army has allocated $10 million of basic research funds for the Institute for Soldier Nanotechnologies at the Massachusetts Institute of Technology (MIT). The purpose of this center of excellence is to develop unclassified nanometer-scale science and technology solutions for the soldier. A single university will host this center, which will emphasize revolutionary materials research toward advanced soldier protection and survivability capabilities. The Naval Research Laboratory has initiated a Nanoscience Institute to enhance multidisciplinary thinking and critical infrastructure.
Nanoscience shows great promise for arrays of inexpensive, integrated,
miniaturized sensors for chemical / biological / radiological / explosive
(CBRE) agents, for nanostructures enabling protection against agents,
and for nanostructures that neutralize agents. The recent terrorist events
motivate accelerated insertion of innovative technologies to improve the
national security posture relative to CBRE. DOD will play a major role
in this multiagency effort.5
In FY 2004, the total request is $197 million, including for defense programs (see Table I-10). This is an increase of $64 million over the FY 2003 request. Fundamental research to understand the properties of materials at the nanoscale would be increased in three areas: synthesis and processing of materials at the nanoscale, condensed matter physics, and catalysis. In addition, the FY 2004 request includes a larger investment for centers. Construction will proceed on two Nanoscale Science Research Centers (NSRC), and engineering and design will continue on others. NSRCs are user facilities for the synthesis, processing, fabrication, and analysis of materials at the nanoscale. NSRCs were conceived within the context of the NSTC Interagency Working Group on Nanoscale Science, Engineering, and Technology as part of the DOE contribution to the National Nanotechnology Initiative. They involve conventional construction of a simple laboratory building, usually sited adjacent to or near an existing DOE Basic Energy Sciences (BES) synchrotron or neutron scattering facility. The research activity will also benefit by new work proposed in FY 2004 by the Office of Advanced Scientific Computing Research (ASCR) in the area of computational nanoscale science engineering and technology. ASCR will develop the specialized computational tools for nanoscale science.
The web site of the NIH roadmap initiatives (http://nihroadmap.nih.gov/).
The FY 2004 request is $70 million, $5 million over the FY 2003 request.
NIH would receive nanoscience and nanotechnology grant applications under
existing and renewed programs. These programs are managed individually
by the Institutes and Centers, with peer review conducted for the most
part by the NIH Center for Scientific Review. Overall nanotechnology program
coordination occurs through the NIH Bioengineering Consortium (BECON).
NIH plans to increase its focus on biological and medical applications
of nanotechnology.
The FY 2004 NASA NNI request is approximately $31 million (see Table I-10). In addition to the $22 million in both Basic Nanoscience and Nanotechnology Research, NASA plans to invest approximately an additional $9 million in the area of Nanotechnology Science and Applications. These investments are embedded within several program areas within the Office of Biological and Physical Research and the Office of Aerospace Technology (OAT). The Basic NASA Nanoscience Program comprises Bio-Molecular Systems Research, which is a joint NASA/NCI (National Cancer Institute) Initiative, and the second is in Biotechnology and Structural Biology. The OAT Program integrates Nanotechnology development in three areas: (1) Materials and Structures, (2) Nanoelectronics and Computing, and (3) Sensors and Spacecraft Components. A major focus at NASA is to advance and exploit the zone of convergence between nanotechnology, biotechnology, and information technology.
Collaboration is particularly important for NASA, since it recognizes
the importance of importing technologies from other federal agencies,
particularly NSF, DOD, the National Institutes of Health (NIH), and the
Department of Energy (DOE). NASA will focus primarily on NASA-unique needs;
examples are low power devices and high strength materials that perform
with exceptional autonomy in the hostile space environment. NASA has increased
university participation in nanotechnology programs by competitively awarding
four University Research, Engineering and Technology Institutes (RETIs)
in FY 2003. Each award is for about $3 million a year for five years with
the option to extend award for up to an additional five years.
The FY 2004 request is $62 million, a $7 million decrease from the FY 2003 request (see Table I-10). Projects in the following areas will be funded: molecular electronics; quantum computing; nanomagnetodynamics; nanotribology; and autonomous atom assembly. Approximately half of the total allocated funds will be used to continue current internal efforts in several of these areas and half will be used to leverage existing efforts with external partners. The funds are distributed, using a competitive process, across the NIST Laboratories for enabling infrastructural measurement, standards, and data for nanomagnetics, nanocharacterization, and new information technologies. Areas of focus are: (a) Nanomagnetics research for measurement and standards for current and near-term applications of nanotechnology in the semiconductor, communications, and health care industries; (b) Nanocharacterization research to produce standards and tools for visualization and characterization at the nanoscale, which are in high demand by a broad base of U.S. industries; (c) Research to provide fundamental measurements needed for future generations of information technology hardware that will be needed to replace semiconductor electronics technology in about a decade. In order to leverage internal efforts, NIST will develop stronger strategic alliances and collaborations with universities, businesses, and other government agencies that possess leading expertise in nanotechnology. NIST plans to direct half of the new nanotechnology funding to these external organizations to conduct much of the specific work required to meet the goals of this initiative and avoid developing costly, complex in-house capabilities that may only be used once. NIST has a large range of collaborations with industry.
FY 2004 research is expected to be similar to FY 2003 at approximately $5 million. EPA's research is organized around the risk assessment/risk management paradigm. Research on human health and environmental effects, exposure, and risk assessment is combined to inform decisions on risk management. Research on environmental applications and implications of nanotechnology can be addressed within this framework. Nanotechnology may offer the promise of improved characterization of environmental problems, significantly reduced environmental impacts from "cleaner" manufacturing approaches, and reduced material and energy use. The potential impacts of nanoparticles from different applications on human health and the environment will be an area of focus.
The FY 2004 request is approximately $10 million, about 10 times larger than FY 2003 request. USDA conducts its research both extramurally through the partnership between the Cooperative State Research, Education, and Extension Service (CSREES) and the Land Grant Universities (LGUs), and in-house at Agriculture Research Service (ARS) national laboratories. The CSREES also provides leadership and financial supports in education and outreach in all the states and territories of the U.S. through the LGUs.
The FY 2004 research request is approximately $2 million for the Transportation Security Administration (TSA) to address one of the agency's most critical missions today: ensuring the security of our nation's air transportation system by improving the detection of explosives and chemical/biological weapons. R&D programs aim to detect explosives and hazardous chemicals at the nanometer level and to characterize the interactions of explosives on material surfaces at this scale. Further research will yield sensor technologies that are cheaper and lighter yet far more sensitive, selective, and reliable than current systems. The NNI activities proposed for FY 2004 will build on current efforts to expedite the fielding of far more accurate and effective security technology at our nation's airports.
In FY 2004 the budget request is steady at $1.4 million. The DOJ National
Institute of Justice (NIJ) has two separate projects areas that incorporate
nanotechnology-DNA Research ($1.0 million) and Development and Chemical
and Biological Defense ($0.4 million). The DNA Research and Development
program will continue basic research as well as the demonstration of chip-based
or micro-device technologies to analyze DNA in forensic applications.
Nanotechnology has or will be a significant part of the device under development
that will eventually be integrated into the current crime laboratory processes
and protocols to analyze forensic DNA samples. The Chemical and Biological
Defense program is developing a wearable, low-cost device to provide warning
of exposure to unanticipated chemical and biological hazards in sufficient
time for its wearer to take effective protective measures. The current
approach relies on an enzymatic reaction. It is based on vapor exposure
of an immobilized enzyme surface. Evolving nanotechnology may be used
to address limitations of the enzymatic approach.
Table I-10a. Agency Participation and Level of Funding in the NNI:
Federal Department or Agency |
FY 2003 |
FY 2004 |
FY 2005 |
---|---|---|---|
National Science Foundation |
221 |
254 |
305 |
Department of Defense |
322
|
315
|
276
|
Department of Energy |
134
|
203
|
211
|
National Institutes of Health |
78
|
80
|
89
|
NIST |
64
|
63
|
53
|
NASA |
36
|
37
|
35 |
Environmental Protection Agency |
5 |
5 |
5 |
Homeland Security (TSA) |
1 |
1 |
1 |
Department of Agriculture |
0 |
1 |
5 |
Department of Justice |
1 |
2 |
2 |
Total |
862 |
961
|
982 |
Table I-10b. NNI centers and networks of excellence
Center Name |
Institution |
||
---|---|---|---|
NSF |
|||
Nanoscale Systems in Information Technologies, NSEC (Nanoscale Science and Engineering Center) |
Cornell University |
||
Nanoscience in Biological and Environmental Engineering |
Rice University |
||
Integrated Nanopatterning and Detection, NSEC |
Northwestern University |
||
Electronic Transport in Molecular Nanostructures, NSEC |
Columbia University |
||
Nanoscale Systems and their Device Applications, NSEC |
Harvard University |
||
Directed Assembly of Nanostructures, NSEC |
Rensselaer Polytechnic Institute |
||
Nanobiotechnology, Science and Technology Center |
Cornell University |
||
NSEC |
UCLA |
||
NSEC |
UIUC |
||
ERC |
U. Colorado, Boulder |
||
DOD |
|||
Institute for Soldier Nanotechnologies |
MIT |
||
Center for Nanoscience Innovation for Defense |
UC Santa Barbara |
||
Nanoscience Institute |
Naval Research Laboratory |
||
NASA |
|||
Institute for Cell Mimetic Space Exploration |
UCLA |
||
Institute for Intelligent Bio-Nanomaterials & Structures for Aerospace Vehicles |
Texas A&M |
||
Bio-Inspection, Design and Processing of Multi-functional Nanocomposites |
Princeton |
||
Institute for Nanoelectronics and Computing |
Purdue |
Table I-10c. NNI R&D user facilities
Center Name |
Institution |
||
---|---|---|---|
NSF |
|||
National Nanofabrication Infrastructure Network (NNUN) - 13 noodes |
Cornell University - central node |
||
Network for Computational Nanotechnology |
Purdue University - central node |
||
DOE |
|||
Center for Functional Nanomaterials |
Brookhaven National Laboratory
|
||
Center for Integrated Nanotechnologies |
Sandia NL and Los Almos NL
|
||
Center for Nanophase Maerials Sciences |
Oak Ridge National Laboratory
|
||
Center for Nanoscale Materials |
Argonne National Laboratory |
||
Molecular Foundry |
Lawrence Berkeley National Laboratory |
* Note: The NNUN predates the NNI, but is now continuing under NNI funding.
Footnotes:
1The author is Senior Advisor to the National Science Foundation, and Chair of NSTC's Subcommittee on Nanoscale Science, Engineering and Technology (NSET). The views expressed in this paper are not necessarily those of NSF or NSET.
2See the NNI's website http://nano.gov.
3Details will be published in "NNI - R&D Supporting the Next Industrial Revolution", Supplemental Report to the President's FY 2005 Budget, Washington, D.C. (estimated to be released in June 2004).
4The FY 2004 program solicitations can be found at http://www.nsf.gov/nano (Nanoscale Science and Engineering, NSF 03-043; and Nanoscale Science and Engineering Education, NSF 03-044) including exploratory, interdisciplinary teams and centers for research and education.
5The DOD nanotechnology budgets and programs are identified at http://nano.gov or http://www.nanosra.nrl.navy.mil.