Science policy of the United States

The science policy of the United States is the responsibility of many organizations throughout the federal government. Much of the large-scale policy is made through the legislative budget process of enacting the yearly federal budget, although there are other legislative issues that directly involve science, such as energy policy, climate change, and stem cell research. Further decisions are made by the various federal agencies which spend the funds allocated by Congress, either on in-house research or by granting funds to outside organizations and researchers.

Federal funding of basic and applied research by year. The spike in 2009 is due to the American Reinvestment and Recovery Act. Figures for 2014 are requested levels.[1]

Professor N. Rosenberg, one of the pioneers of technological innovation research, pointed out that industrial research laboratories (R&D), if not the most important institutional innovations in institutional innovation in the 20th century, are also one of the most important institutional innovations. Although not the first invention of the United States, this system has a wider spread and stronger influence in the US economy than in other countries.

The USA devoted 2.81% of GDP to research and development (R&D) in 2012. The private sector contributed two-thirds of the total. The Obama administration had fixed a target of a 3% ratio by the end of his presidency in 2016.[2]

Legislating science policy

In the Executive Office of the President, the main body advising the president on science policy is the Office of Science and Technology Policy. Other advisory bodies exist within the Executive Office of the President, including the President's Council of Advisors on Science and Technology and the National Science and Technology Council.

In the United States Congress, a number of congressional committees have jurisdiction over legislation on science policy, most notably the House Committee on Science and Technology and the Senate Committee on Commerce, Science and Transportation, and their subcommittees. These committees oversee the various federal research agencies that are involved in receiving funding for scientific research. Oversight of some agencies may fall under multiple committees, for example the Environmental Protection Agency.[3]

The number of Congressional members and other politicians with backgrounds in science, engineering, and technology has grown in recent years, with the 116th Congress setting a record with 47 of 535 members with STEM backgrounds.[4] Therefore, most U.S. politicians refer to various Congressional support agencies for analysis on science related issues, which do not solely focus on science, but provide insight for Congress to make decisions dealing with scientific issues. These agencies are nonpartisan and provide objective reports on topics requested by members of congress. They are the Congressional Research Service, Government Accountability Office, and Congressional Budget Office.[4] In the past, the Office of Technology Assessment provided Congressional members and committees with objective analysis of scientific and technical issues, but this office was abolished as a result of the Republican Revolution of 1994.[5]

Further advice is provided by extragovernmental organizations such as The National Academies, which was created and mostly funded by the federal government,[6] and the RAND Corporation, as well as other non-profit organizations such as the American Association for the Advancement of Science and the American Chemical Society among others.

Research and development in the federal budget

The research and development budget by department in the Obama administration's federal budget proposal for fiscal year 2015.[7][8]
United States Department of the Air ForceUnited States Department of the NavyUnited States Department of the ArmyUnited States Department of DefenseNational Institutes of HealthUnited States Department of Health and Human ServicesUnited States Department of EnergyNASANational Science FoundationUnited States Department of AgricultureUnited States Department of CommerceUnited States Department of Veterans AffairsUnited States Department of the InteriorUnited States Department of Homeland SecurityUnited States Department of TransportationUnited States Environmental Protection AgencyPatient-Centered Outcomes Research InstituteUnited States Department of EducationSmithsonian InstitutionOther: $0.698B

Only a small percentage of the overall federal budget is allocated to R&D. The FY2015 budget request includes $135.110B in R&D spending[7] out of a total budget of $3969.069B, representing 3.4% of the budget.[9] Research and development funding in the federal budget is not centrally enacted, but is spread across many appropriations bills which are enacted in the annual United States budget process. Of the twelve annual appropriations bills, the most important for R&D are those for Defense; Labor, Health and Human Services, and Education (which includes NIH); Commerce, Justice, and Science (which includes NSF, NASA, NIST, and NOAA); and Energy and Water Development. Other appropriations bills include smaller amounts of R&D funding.

There are a number of federal agencies across the government which carry out science policy. Some of these primarily perform their own research "in-house", while others grant funds to external organizations or individual researchers. In addition, the federally funded research and development centers, which include most of the U.S. National Laboratories, are funded by the government but operated by universities, non-profit organizations, or for-profit consortia.

The FY2015 presidential budget request defines R&D as "the collection of efforts directed toward gaining greater knowledge or understanding and applying knowledge toward the production of useful materials, devices, and methods." R&D is divided into five subcategories. Basic research is directed toward understanding of the fundamental aspects of observable phenomena. It may be directed towards broad but not specific applications. Applied research is directed towards gaining knowledge to meet a recognized and specific need. Development is the application of knowledge or understanding for the production of useful materials, devices, and methods, including production of prototypes. R&D equipment includes acquisition or production of movable equipment, such as spectrometers, research satellites, or detectors. R&D facilities include the construction or major repairs to physical facilities including land, buildings, and fixed capital equipment such fixed facilities as reactors, wind tunnels, and particle accelerators.[10]

The following chart shows a breakdown for the five agencies with the largest R&D budgets in the Obama administration's FY2015 proposal:[10]

10
20
30
40
50
60
70
  •   Basic research
  •   Applied research
  •   Development
  •   Equipment and facilities

Defense research and development

Defense R&D has the goal of "maintaining strategic technological advantages over potential foreign adversaries."[11] As of 2009, just over half of the R&D budget was allocated to defense spending.[12] Most Defense R&D falls under the Research, Development, Test, and Evaluation (RTD&E) budget, although some R&D funding is outside this budget, such as the Defense Health Program and the chemical weapons destruction program. The Department of Defense divides development further, giving each category a code: 6.1 is Basic Research, 6.2 is Applied Research, 6.3 is Advanced Technology Development, 6.4 is Advanced Component Development and Prototypes, 6.5 is System Development and Demonstration, 6.6 is RDT&E Management and Support, and 6.7 is Operational Systems Development.[11]

Most of the Defense R&D budget is for weapon systems development, with nearly all activity in categories 6.4 and higher carried out by private defense contractors. About one sixth of it is allocated to the Science and Technology (S&T) program, which includes all of 6.1, 6.2, 6.3, and medical research. As of 2013, research funding (6.1 and 6.2) was disbursed 40% to industry, 33% to DoD laboratories, and 21% to academia.[13] The Department of Defense was the third-largest supporter of R&D in academia in FY2012, with only NIH and NSF having larger investments, with DoD the largest federal funder for engineering research and a close second for computer science.[11]

The Defense Research Enterprise (DRE) consists of S&T programs within each of the three military departments within DoD. The budget is prepared by each department's acquisition secretary, namely the Assistant Secretary of the Air Force (Acquisition), Assistant Secretary of the Navy (Research, Development and Acquisition), and Assistant Secretary of the Army for Acquisition, Logistics, and Technology. Air Force S&T is executed by the Air Force Materiel Command's Air Force Research Laboratory (AFRL). Navy S&T is executed by the Office of Naval Research (ONR), with medical research performed by the Navy Bureau of Medicine and Surgery. For the Army, 72% of the S&T budget is in Army Materiel Command's Research, Development and Engineering Command (RDECOM), with the remainder in Army Medical Research and Materiel Command (USAMRMC), Army Corps of Engineers (USACE), Army Space and Missile Defense Command (USASMDC) and the Deputy Chief of Staff (G1-Personnel) to the Assistant Secretary of the Army (Manpower and Reserve Affairs). Each agency supports both in-house intramural research as well as grants to outside academic or industrial organizations.[14]

The following chart shows a breakdown for the agencies with the most R&D funding within the Department of Defense in the Obama administration's FY2015 proposal. The "Other" category includes $3.7B for classified programs such as NSA, DIA, and NGA, whose top-level budget numbers are not released, as well as the uncategorized R&D funds not included in the RDT&E budget.[8]

5
10
15
20
25
30
  •   Basic Research (6.1)
  •   Applied Research (6.2)
  •   Advanced Technology Development (6.3)
  •   Advanced Component Development and Prototypes (6.4)
  •   System Development and Demonstration (6.5)
  •   Management and Support (6.6)
  •   Operational Systems Development (6.7)
  •   Uncategorized

Intellectual property policy

Inventions "conceived or actually reduced to practice" in the performance of government-funded research may be subject to the Bayh-Dole Act.

The Federal Research Public Access Act (111th congress S.1373, introduced 25 June 2009 but still in a Senate committee) would require "free online public access to such final peer-reviewed manuscripts or published versions as soon as practicable, but not later than 6 months after publication in peer-reviewed journals".[15][16][17]

The America Invents Act of 2011 moved the US from a 'first to invent' system to a 'first to file' model, the most significant patent reform since 1952. This act will limit or eliminate lengthy legal and bureaucratic challenges that used to accompany contested filings. However, the pressure to file early may limit the inventor's ability to exploit the period of exclusivity fully. It may also disadvantage very small entities, for which the legal costs of preparing an application are the main barrier to filing. This legislation has also fostered the rise of what are familiarly known as patent trolls.[2]

Science in political discourse

Most of the leading political issues in the United States have a scientific component. For example, healthcare, renewable energy, climate change, and national security. Amongst U.S. public opinion, 60% of Americans believe scientific experts should play an active role in policy debates over relevant issues, although this view is divided amongst Democrats and Republicans.[18] Broadly, a majority of Americans believe that scientists should be involved in shaping policies related to medical and health, energy, education, environmental, infrastructure, defense, and agriculture policies.[19]

Science policy in the states

State government initiatives

There are also a number of state and local agencies which deal with state-specific science policy and provide additional funding, such as the California Institute for Regenerative Medicine.

Overall research spending in the states

Contribution of each state to US research in 2010, in terms of funding (public and private sectors) and science and engineering occupations. Source: Figure 5.6 from the UNESCO Science Report: towards 2030, based on data from National Science Foundation

The level of research spending varies considerably from one state to another. Six states (New Mexico, Maryland, Massachusetts, Washington, California and Michigan) each devoted 3.9% or more of their GDP to R&D in 2010, together contributing 42% of national research expenditure. In 2010, more than one-quarter of R&D was concentrated in California (28.1%), ahead of Massachusetts (5.7%), New Jersey (5.6%), Washington State (5.5%), Michigan (5.4%), Texas (5.2%), Illinois (4.8%), New York (3.6%) and Pennsylvania (3.5%). Seven states (Arkansas, Nevada, Oklahoma, Louisiana, South Dakota and Wyoming) devoted less than 0.8% of GDP to R&D.[2]

California is home to Silicon Valley, the name given to the area hosting the leading corporations and start-ups in information technology. This state also hosts dynamic biotechnology clusters in the San Francisco Bay Area, Los Angeles and San Diego. The main biotechnology clusters outside California are the cities of Boston/Cambridge, Massachusetts, Maryland, suburban Washington DC, New York, Seattle, Philadelphia and Chicago. California supplies 13.7% of all jobs in science and engineering across the country, more than any other state. Some 5.7% of Californians are employed in these fields. This high share reflects a potent combination of academic excellence and a strong business focus on R&D: the prestigious Stanford University and University of California rub shoulders with Silicon Valley, for instance. In much the same way, Route 128 around Boston in the State of Massachusetts is not only home to numerous high-tech firms and corporations but also hosts the renowned Harvard University and Massachusetts Institute of Technology.[2]

New Mexico's high research intensity can be explained by the fact that it hosts both Los Alamos National Laboratory and the primary campus of Sandia National Laboratories, the two major United States Department of Energy research and development national laboratories. Maryland's position may reflect the concentration of federally funded research institutions there. Washington State has a high concentration of high-tech firms like Microsoft, Amazon and Boeing and the engineering functions of most automobile manufacturers are located in the State of Michigan.[2]

Microsoft, Intel and Google figured among the world's top 10 corporations for research spending in 2014. They shared this distinction with Johnson & Johnson, a multinational based in New Jersey which makes pharmaceutical and healthcare products, as well as medical devices, and were closely followed by automobile giant General Motors (11th), based in Detroit, and pharmaceutical companies Merck (12th) and Pfizer (15th). Merck is headquartered in New Jersey and Pfizer in New York. Intel's investment in R&D has more than doubled in the past 10 years, whereas Pfizer's investment has dropped since 2012. Several pharmaceutical companies figure among the top 15 corporations for research spending. The USA carries out almost half (46%) of all research in the life sciences, making it the world leader. In 2013, US pharmaceutical companies spent US$40 billion on R&D inside the US and nearly another US$11 billion on R&D abroad. Some 7% of the companies on Thomson Reuters' Top 100 Global Innovators list for 2014 are active in biomedical research, equal to the number of businesses in consumer products and telecommunications.[2]

Global top 50 companies by R&D volume and intensity, 2014

Rank in 2014CompanyCountryFieldR&D (€ millions)Change in rank for R&D, 2004–2014Research intensity (R&D expenditure divided by net sales)
1 Volkswagen Germany Automobiles & parts 11743 +7 6.0
2 Samsung Electronics Rep. Korea Electronics 10155 +31 6.5
3 Microsoft USA Computer hardware and software 8253 +10 13.1
4 Intel USA Semiconductors 7694 +10 20.1
5 Novartis Switzerland Pharmaceuticals 7174 +15 17.1
6 Roche Switzerland Pharmaceuticals 7076 +12 18.6
7 Toyota Motors Japan Automobiles & parts 6270 −2 3.5
8 Johnson & Johnson USA Medical equipment, pharmaceuticals, consumer goods 5934 +4 11.5
9 Google USA Internet-related products and services 5736 +173 13.2
10 Daimler Germany Automobiles & parts 5379 −7 4.6
11 General Motors USA Automobiles & parts 5221 −5 4.6
12 Merck USA USA Pharmaceuticals 5165 +17 16.2
13 BMW Germany Automobiles & parts 4792 +15 6.3
14 Sanofi-Aventis France Pharmaceuticals 4757 +8 14.4
15 Pfizer USA Pharmaceuticals 4750 −13 12.7
16 Robert Bosch Germany Engineering and electronics 4653 +10 10.1
17 Ford Motors USA Automobiles & parts 4641 −16 4.4
18 Cisco Systems USA Networking equipment 4564 +13 13.4
19 Siemens Germany Electronics & electrical equipment 4556 −15 6.0
20 Honda Motors Japan Automobiles & parts 4367 −4 5.4
21 Glaxosmithkline UK Pharmaceuticals & biotechnology 4154 −10 13.1
22 IBM USA Computer hardware, middleware & software 4089 −13 5.7
23 Eli Lilly USA Pharmaceuticals 4011 +18 23.9
24 Oracle USA Computer hardware & software 3735 +47 13.5
25 Qualcomm USA Semiconductors, telecommunications equipment 3602 +112 20.0
26 Huawei China Telecommunications equipment and services 3589 >200 25.6
27 Airbus Netherlands* Aeronautics 3581 +8 6.0
28 Ericsson Sweden Telecommunications equipment 3485 −11 13.6
29 Nokia Finland Technology hardware & equipment 3456 −9 14.7
30 Nissan Motors Japan Automobiles & parts 3447 +4 4.8
31 General Electric USA Engineering, electronics & electrical equipment 3444 +6 3.3
32 Fiat Italy Automobiles & parts 3362 +12 3.9
33 Panasonic Japan Electronics & electrical equipment 3297 −26 6.2
34 Bayer Germany Pharmaceuticals & biotechnology 3259 −2 8.1
35 Apple USA Computer hardware & software 3245 +120 2.6
36 Sony Japan Electronics & electrical equipment 3209 −21 21.3
37 Astrazeneca UK Pharmaceuticals & biotechnology 3203 −12 17.2
38 Amgen USA Pharmaceuticals & biotechnology 2961 +18 21.9
39 Boehringer Ingelheim Germany Pharmaceuticals & biotechnology 2743 +23 19.5
40 Bristol–Myers Squibb USA Pharmaceuticals & biotechnology 2705 +2 22.8
41 Denso Japan Automobile parts 2539 +12 9.0
42 Hitachi Japan Technology hardware & equipment 2420 −18 3.7
43 Alcatel–Lucent France Technology hardware & equipment 2374 +4 16.4
44 EMC USA Computer software 2355 +48 14.0
45 Takeda Pharmaceuticals Japan Pharmaceuticals & biotechnology 2352 +28 20.2
46 SAP Germany Software & computer services 2282 +23 13.6
47 Hewlett–Packard USA Technology hardware & equipment 2273 −24 2.8
48 Toshiba Japan Computer hardware 2269 −18 5.1
49 LG Electronics Korea, Rep. Electronics 2209 +61 5.5
50 Volvo Sweden Automobiles & parts 2131 +27 6.9

* Although incorporated in the Netherlands, Airbus's principal manufacturing facilities are located in France, Germany, Spain and the UK.

Source: UNESCO Science Report: towards 2030 (2015), Table 9.3. Based on Hernández et. al (2014) EU R&D Scoreboard: the 2014 EU Industrial R&D Investment Scoreboard. European Commission: Brussels, Table 2.2.

History

The first President's Science and Technology Advisor was James R. Killian, appointed in 1958 by President Dwight D. Eisenhower after Sputnik Shock created the urgency for the government to support science and education. President Eisenhower realized then that if Americans were going to continue to be the world leader in scientific, technological and military advances, the government would need to provide support. After World War II, the US government began to formally provide support for scientific research and to establish the general structure by which science is conducted in the US.[20] The foundation for modern American science policy was laid way out in Vannevar Bush's Science – the Endless Frontier, submitted to President Truman in 1945. Vannevar Bush was President Roosevelt's science advisor and became one of the most influential science advisors as, in his essay, he pioneered how we decide on science policy today.[21] He made recommendations to improve the following three areas: national security, health, and the economy—the same three focuses we have today.

Creation of the NSF

The creation of the National Science Foundation, although implemented in 1950, was a controversial issue that started as early as 1942, between engineer and science administrator Vannevar Bush and Senator Harley M. Kilgore (D-WV), who was interested in the organization of military research. Senator Kilgore presented a series of bills between 1942–1945 to Congress, the one that most resembles the establishment of the NSF, by name, was in 1944, outlining an independent agency whose main focus was to promote peacetime basic and applied research as well as scientific training and education. Some specifics outlined were that the director would be appointed and the board would be composed of scientists, technical experts and members of the public. The government would take ownership of intellectual property developed with federal funding and funding would be distributed based on geographical location, not merit. Although both Bush and Kilgore were in favor of government support of science, they disagreed philosophically on the details of how that support would be carried out. In particular, Bush sided with the board being composed of just scientists with no public insight. When Congress signed the legislation that created the NSF, many of Bush's ideals were removed. It illustrates that these questions about patent rights, social science expectations, the distribution of federal funding (geographical or merit), and who (scientists or policymakers) get to be the administrators are interesting questions that science policy grapples with.

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See also

References

 This article incorporates text from a free content work. Licensed under CC-BY-SA IGO 3.0 UNESCO Science Report: towards 2030, UNESCO. To learn how to add open license text to Wikipedia articles, please see this how-to page. For information on reusing text from Wikipedia, please see the terms of use.

  1. "The 2014 Budget: A World-Leading Commitment to Science and Research" (PDF). Office of Science and Technology Policy. Retrieved 19 March 2014.
  2. Stewart, Shannon; Springs, Stacy (2015). United States of America. In: UNESCO Science Report: towards 2030. Paris: UNESCO. ISBN 978-92-3-100129-1.
  3. White, Kasey; Carney, Joanne (2011). Working with Congress: A Scientist's Guide to Policy (PDF). Washington, D.C.: AAAS. pp. 20–23. ISBN 978-0-87168-740-1.
  4. White, Kasey Shewey. (2011). Working with congress : a scientist's guide to policy. [Place of publication not identified]: Aaas. ISBN 978-0871687401. OCLC 729687228.
  5. Public Law 104–53, Title I, Sections 113–114, 19 November 1995 https://uscode.house.gov/statviewer.htm?volume=109&page=526
  6. "Frequently asked questions". The National Academies. Retrieved 29 April 2011.
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  8. "FY2015 Department of Defense Budget: RTD&E Programs (R-1)" (PDF). Office of the Under Secretary of Defense (Comptroller). June 2014. p. II. Retrieved 27 July 2014.
  9. "Table 28-1: Policy Budget Authority and Outlay by Function, Category, and Program" (PDF). Analytical Perspectives, Budget of the United States Government, Fiscal Year 2015. United States Office of Management and Budget. Retrieved 22 May 2014.
  10. "Special Topics" (PDF). Analytical Perspectives, Budget of the United States Government, Fiscal Year 2015. U.S. Office of Management and Budget. pp. 312–315. Retrieved 25 July 2014.
  11. Doom, Travis R. "Department of Defense" (PDF). American Association for the Advancement of Science. Retrieved 1 August 2014.
  12. Koizumi, Kei. "Federal R&D in the FY 2009 Budget: An Introduction". AAAS. Retrieved 20 August 2010.
  13. "Federal R&D Funding: Quick Agency Profiles". Proposal Exponent. Retrieved 28 July 2014.
  14. National Research Council (2014). Strategic Engagement in Global S&T: Opportunities for Defense Research. Washington, DC: The National Academies Press. pp. 28–35. Retrieved 1 August 2014.
  15. Federal Research Public Access Act
  16. Library of Congress, S.1273
  17. US Scientific Grant Awards Database Archived 6 November 2010 at the Wayback Machine
  18. Pew Research Center (August 2019). "Trust and Mistrust in Americans' Views of Scientific Experts" (PDF).
  19. Research!America (March 2019). "America Speaks: Poll Data Summary, Volume 19" (PDF).
  20. Neal, Homer; Smith, Tobin; McCormick, Jennifer (2008). Beyond Sputnik. The University of Michigan Press.
  21. Ehlers, Vernon (16 January 1998). "The Future of U.S. Science Policy". Science. 279 (5349): 302a–302. Bibcode:1998Sci...279..302E. doi:10.1126/science.279.5349.302a.
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