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prOmO CODE IrA1402
Government and Science:
A Dangerous Liaison?
—————— ✦ ——————
WILLIAM N. BUTOS AND
THOMAS J. MCQUADE
W
ith the rise of the modern state, science has become increasingly subject
to government intervention in its funding and direction. This tendency’s
underlying driving force has been the growth of government itself. The
governmental impetus to ensure politically determined adequate levels of scientific
research and development (R&D) and to manage such efforts took hold in the twentieth century principally as a consequence of nationalistic hostilities or perceived threats
of external aggression. This rationale was eventually augmented by more broadly
based social agendas and by the “market failure” claim that academic economists
advanced in the late 1950s (and since) with respect to the production of R&D, especially so-called basic research (see, for example, Nelson 1959; Griliches 1960; Arrow
1962). Since 1949, as shown in figure 1, the extent of government engagement in
science has trended upward significantly, and the prevalent thinking of our times is
that only fiscal constraints limit the magnitude of government funding of science.
There are serious reasons, however, for thinking that the liaison between government and science carries with it unrecognized dangers for the functioning and integrity
of science as a reliable generator of knowledge. It is not so much that government
seeks to exert a blatant and crude control over the content and direction of scientific
inquiry—although such heavy-handed intrusion has precedents, most notably in the
William N. Butos is a professor of economics at Trinity College, Hartford; Thomas J. McQuade is a
visiting scholar in the Department of Economics at New York University.
The Independent Review, v. XI, n. 2, Fall 2006, ISSN 1086–1653, Copyright © 2006, pp. 177–208.
177
178
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W I L L I A M N . B U T O S A N D T H O M A S J. M C Q U A D E
Figure 1
Federal Spending on Defense and Nondefense
R&D, 1949–2007
(billions of 2001 dollars)
30
20
10
00
90
80
70
60
50
40
30
20
10
0
1949
1957
1965
1973
Nondefense R&D
1981
1989
1997
2005
Defense R&D
Note: Fiscal year 2007 is president’s request.
Source: American Association for the Advancement of Science 2006a. Based on Office of
Management and Budget in Budget of the United States Government FY 2007.
USSR—but that the structure and conduct of seemingly benign and generous government funding of science has side effects that generate instabilities in scientific activity
in the short run and corrode the structure and adaptability of the system of science
itself in the long run.
In this article, we briefly survey the relationship between government and science, concentrating on the situation in the United States in the twentieth century. We
discuss in some detail the theoretical rationale for government funding, showing that
it is open to serious question: its model of market failure in science is highly suspect,
and its implications for the remedial effects of intervention do not stand up to even
casual empirical scrutiny. Calling attention to the nakedness of the standard economic
rationale, however, does not touch the actual political rationales. Following other
commentators—Greenberg (2001), in particular—we direct attention to the interaction between these rationales and scientists’ understandably strong desire to have their
work well funded. Although we find Greenberg’s and others’ detailed descriptions of
unease within science to be compelling, we think they suffer from a lack of any clear
theoretical model of science as a social system. Therefore, to point the way toward a
more comprehensive treatment, we devote considerable attention to an exposition of
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the various ways in which government funding interacts with scientists and the system
of scientific activity to produce the unanticipated effects that concern us.
Historical Background
The U.S. government has funded isolated scientific research projects (broadly conceived)
since the early days of the republic, as evidenced, for example, by the War Department’s
support of the Lewis and Clark Expedition and the congressional appropriation to support Samuel Morse’s electric telegraph. The Civil War accelerated and broadened a federal presence in science, including the use of scientific advisors for wartime purposes and
the congressional establishment of the National Academy of Science (NAS) in 1863.
The federal government established the Department of Agriculture and the land-grant
system of colleges, both of which provided institutional bases for government-funded
scientific research that have persisted to this day. The Pure Food and Drug Act of 1906
established a permanent regulatory demand for scientific expertise. With the outbreak
of World War I, the Navy Department constituted a naval consulting board (headed by
Thomas Edison) to seek out applications of technologies for military purposes; it would
become the Naval Research Laboratory after the war. President Woodrow Wilson created the National Research Council (NRC) as an offshoot of the NAS to study the
government’s scientific needs. The NRC coordinated wartime projects in optics and gas
warfare that involved the military, private contractors, and government-sponsored university R&D. At the end of the war, this government-industry-university establishment
was largely dismantled, and although the NRC was given permanent status, its activities
during the 1920s greatly diminished owing to a lack of funding (see Dupré and Lakoff
1962; Rahm, Kirkland, and Bozeman 2000, chap. 2).
Although a government presence in scientific and technological R&D was well
established by the beginning of World War I, it was not based on a principled, coherent,
or explicit “national science policy.” Instead, government support for science served
largely transitory wartime exigencies. But this situation would change under Franklin D.
Roosevelt’s administration with the continuation of the Depression and the approach of
war. In 1933, Roosevelt set up the Presidential Science Advisory Board and the National
Planning Board (NPB) to enlist scientific expertise for solutions to the Depression. In
1934, the National Resources Board (NRB) replaced the NPB and subsumed within its
jurisdiction the Science Advisory Board. As Feldman, Link, and Siegel point out, “after
all the organizational issues were settled, the federal government recognized . . . that it
had and would continue to have an important coordinating role to play in science and
technology planning toward a national goal of economic well-being” (2002, 13).1
1. The idea that science should serve social and political objectives, as opposed to seeking “scientific truth,”
was not confined to America. Indeed, such enthusiasms were especially pronounced in England during the
1930s. Fueled by beliefs in the presumed success of Soviet central planning, the British government came
under increasing pressure to organize scientific institutions so as to establish central planning for science.
This movement was countered, almost single-handedly, by John Baker, Michael Polanyi, and their Society
of Freedom in Science. This episode is analyzed in detail in McGucken 1984.
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Of special note was the NRB’s publication of a 1938 report entitled Research—
A National Treasure, a comprehensive survey of government, industry, and university
scientific activity that would provide the rationale and justification for a governmental
science policy. The report argued that the government
1. is constitutionally obligated to support science and technology related to defense,
scientific standards of weights and measures, and certain regulatory functions;
2. is more effective than the private sector in carrying out research, especially when
private costs of research are high relative to its practical or social value; and
3. can stimulate industry research that is expensive and has unpredictable or delayed
financial payoffs. (see Feldman, Link, and Siegel 2002, 13–14)
Once war broke out again, the government moved to harness scientific resources
for military purposes. Of the 92,000 working scientists prior to the war, about 19,400
were employed in the government, and more than 72,000 were employed, in roughly
equal numbers, at universities and at the more than 2,200 industrial laboratories
(Feldman, Link, and Siegel 2002, 14). In 1940, Roosevelt established the National
Defense Research Committee, replaced in 1941 by the Office of Scientific Research
and Development (OSRD), to organize scientific and technological resources for the
war effort. Under the chairmanship of Vannevar Bush, the former president of the
Carnegie Institution in Washington and a one-time vice president of MIT, the OSRD
did not conduct research, but it did establish contractual relations—a protocontractual
framework—governing collaboration between government funding agencies and university and industry entities that undertook and administered sanctioned research.2
As World War II drew to a close, no concerted effort was made to dismantle
the government’s wartime involvement in science, in contrast to the post-World War
I experience. Instead, Roosevelt asked Bush to prepare a report analyzing how the
OSRD’s role could be played in peacetime collaboration of government and the scientific community for achieving “improvement of the national health, the creation
of enterprises bringing new jobs, and the betterment of the national standard of living.”3 Bush’s report, published in 1945 as Science—the Endless Frontier, is perhaps the
decisive document charting the institutional framework for science in the latter part
of the twentieth century and into the twenty-first. The report claimed that government support of science is essential for medical advances, national security, economic
welfare, and full employment. Bush argued that attaining these goals required that the
“Federal Government should accept new responsibilities for promoting the creation of
new scientific knowledge and the development of scientific talent in our youth” (25).
This “national policy for scientific research and education” (28) was to be financed by
2. The University of California’s Los Alamos Laboratory in New Mexico is an example of the OSRD’s
efforts. The laboratories built for the Manhattan Project came under the aegis of the OSRD and would
later begin the U.S. national laboratory system.
3. Letter from Roosevelt to Bush, November 17, 1944, quoted in Feldman, Link, and Siegel 2002, 15.
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government funds, making payments to industry and subsidizing research as well as
undergraduate and graduate student scholarships in universities. In addition to recommending expanded support for research and applied work conducted by government
laboratories, the report highlighted the special role that colleges and universities should
play in basic research.4 The institutionalization of the federal government’s reconfigured
role was to be attained by the creation of the National Science Foundation (NSF), whose
purpose was to “develop and promote” federal science policy and to implement policies
aimed at supporting “basic research in non-profit organizations” (28). The report also
charged the NSF with responsibility for developing scientific talent and for supporting
long-range research with military applications.
Bush’s central claim was that material progress depends on new scientific knowledge and that such knowledge, in turn, depends on what he called “basic research”:
research performed without thought of practical ends, as he defined it.5 Implicit in
this claim was the assumption that the federal government must provide the dominant
guiding, coordinating, and financing role for the growth of scientific knowledge. He
rested this assumption on a constitutional claim that the “[f]ederal government, by
virtue of its charge to provide for the common defense and general welfare, has the
responsibility of encouraging and aiding scientific progress” (1945, 68). The connection between national defense and military scientific and technological progress was not
a new justification for an expanded role for government. Justifying this expansive role
with reference to “public health, higher standards of living, conservation of national
resources, new manufacturing which creates new jobs and investment opportunities,
in short, the prosperity, well-being and progress of the American nation” reflected a
vision that was reminiscent of, but surely more politically timely than the 1938 report
Research—A National Treasure. Although the claim that marshaling the amount of
research money necessary to satisfy these objectives requires substantial federal support
appears throughout the 1945 report, no detailed analysis was provided to support it.6
Bush’s report received crucial support with the timely publication in 1947 of
Science and Public Policy: A Program for the Nation, by the President’s Scientific
4. Of the fifty individuals who served on committees that reported to Bush, a majority listed academic
affiliations (generally at the higher administrative levels); the next largest group comprised personnel from
government agencies. The so-called Medical Committee consisted entirely of nine university-affiliated
physicians.
5. See Feldman, Link, and Siegel 2002, 16. Bush’s claim that basic research necessarily precedes applied
R&D and its eventual effects on material progress is often referred to as the “linear model,” a paradigm that
dominated policymakers’ and academic researchers’ views for decades, as we discuss later in more detail.
6. The Bush report’s argument for government funding of science does not rest on claims about market
failure, but on a vague sense that “more scientific knowledge is desirable.” The report in appendix 3 by
the Committee on Science and Public Welfare, the one committee most closely associated with economics,
provides data on scientific research expenditures by industry, colleges and universities, and government.
However, only two economists, Rupert Maclaurin of MIT and Harold Moulton of the Brookings Institute,
sat on this committee, and neither of them ever advanced market-failure arguments for science in their own
academic work. Moulton, who came into prominence in the 1920s, was a leading authority on money,
banking, and business cycles. Maclaurin did write on R&D issues; see, for example, his Research and Innovation in the Radio Industry (1949).
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Research Board under the direction of John Steelman, an assistant to the president. The
Steelman report argued that the government should allocate 1 percent of gross domestic product (GDP) to R&D,7 while reaffirming the centrality of basic research for economic prosperity and growth, the belief that the private sector cannot reliably sustain
such research, and the claim that R&D should be conducted principally by universities
and industry with government funding.8 The Steelman report also called for creation
of a national science foundation to dispense government research funds. Congress did
create the proposed agency in 1950 under the National Science Foundation Act. Since
the 1950s, the essential contours of government and science interaction in the United
States have taken the forms proposed in the Bush and Steelman reports.9 The principal
divergence has been in the magnitude of the funds the government has dispensed.
Thus, the long-standing but largely piecemeal incursion of government into science since the eighteenth century gave way in the twentieth century to the creation
of formal government institutions and associated funding mechanisms during World
War I and especially during World War II. Most of this activity was war related. In the
aftermath of World War II, however, initiatives were taken to promote government
involvement in science on the grounds of economic development as well as national
defense; the Bush and Steelman reports were pivotal in molding government science
policy after World War II. Creation of the NSF in 1950 actually brought to an end a
controversy over science policy within the government that had raged for several years
among those such as Bush and Steelman who argued for an indirect government role
in science (by means of government financing of university and industry science via
a collection of mission-oriented agencies) and those who argued for a direct role (by
means of governmental coordination and management of science). The latter position,
most famously maintained by Democratic senator Harley Kilgore of West Virginia,
envisioned a centralized government agency that would “direct and consciously plan
the advance of scientific research and technology” (Kleinman 1995, 6, emphasis in
original). For about five years, beginning in 1942, Kilgore introduced several legislative proposals for the creation of a centralized government science agency controlled
and administered by representatives of a wide range of social interests, including both
scientists and nonscientists (Kleinman 1995, chap. 5).
The eventual defeat of Kilgore and his New Deal associates by Vannevar Bush,
both in legislation and in the widespread acceptance of Bush’s Science—the Endless
Frontier (1945), is traditionally viewed as a victory for a decentralized approach
(Kleinman 1995; Feldman, Link, and Siegel 2002). But if this outcome can be called
a victory, it was certainly a shallow one. In the aftermath of World War II, government
involvement in science followed the outlines of the Bush approach, but the scale of
7. The Endless Frontier urged that federal funding attain an annual level of $122 million.
8. President’s Scientific Research Board 1947, 1:3–7. The President’s Scientific Research Board was composed entirely of Cabinet secretaries and other government officials, including Vannevar Bush.
9. See Feldman, Link, and Siegel 2002, 19, for an overview.
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government funding swept away historical precedents and established funding norms
that have persisted with little change into the present.
Science Funding since World War II
The precedent for increased government funding of science, established during the war
years with an emphasis on military R&D, and the subsequent legitimizing of a broader
justification for government in science set the stage for substantial increases in government funding after 1949 (see figure 1).10 In 1949, total federal R&D spending (measured
in 2001 dollars) was approximately $5 billion; by 1964, it had increased to approximately
$65 billion--a thirteenfold increase, bolstered by the political considerations that attended
the Cold War. The proportion of defense to nondefense R&D spending was approximately 5 to 1 in 1949 but decreased steadily to approximately 1.4 to 1 by 1963, a ratio
that is typical for much of the period since then. From 1964 to 1969, nondefense spending (of which spending for the National Aeronautics and Space Administration [NASA]
was a large component) increased dramatically, and total R&D spending hovered in the
$60 billion to $70 billion range. From 1970 to 1983, some retrenchment occurred, with
federal spending hovering near the $55 billion mark, but thereafter defense spending
increased sharply (whereas the nondefense component shrank modestly), so that total
R&D spending edged toward $75 billion. Declines in defense spending beginning in
1991 and continuing until 2001 were more than offset by nondefense increases that kept
total federal R&D spending around the $75 billion mark during the decade.
Figure 2, which contains more recent data for total federal R&D expenditures on
defense and nondefense, illustrates more clearly the relative sizes of these two R&D
components. Also, in the years since 2002, R&D outlays for defense have increased
sharply. For fiscal year 2006, the president requested R&D funding of approximately
$130 billion.
We also note that since the mid-1960s, the share of federal R&D expenditures in
total budget outlays has declined and given way to a more or less stable ratio.As shown in
figure 3, this ratio has averaged approximately 5 percent of the federal budget since the
early 1970s. Of course, given the rise in the overall federal budget during this period, the
declining and now stable ratio of federal R&D to total budget outlays still represents significant increases in federal funding for R&D in absolute (and constant dollar) terms.
The empirical data presented in our figures suggest that the explosion of government funding of science following World War II is significant and without precedent.
10. As defined by the NSF, research is “systematic study directed toward fuller scientific knowledge or
understanding of the subject studied,” and it comprises basic research (“systematic study directed toward
fuller knowledge or understanding of the fundamental aspects of phenomena and of observable facts without specific applications toward processes or products in mind”) and applied research (“systematic study
to gain knowledge or understanding necessary to determine the means by which a recognized and specific need may be met”). Development is “systematic application of knowledge or understanding, directed
toward the production of useful materials, devices, and systems or methods, including design, development, and improvement of prototypes and new processes to meet specific requirements” (2005a, 1).
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Figure 2
Trends in Federal R&D Expenditures, 1976–2006
(billions of 2005 dollars)
120
100
TOTAL R&D
80
DEFENSE R&D
60
40
NONDEFENSE R&D
20
2006
2004
2002
2000
1998
1996
1994
1992
1990
1988
1986
1984
1982
1980
1978
1976
0
Note: Fiscal year 2006 data are President’s request.
Source: American Association for the Advancement of Science 2006c. Based on
ASSA Reports VIII–XXX.
Figure 3
Federal R&D Expenditures as a Percentage of
Federal Budget Outlays, 1962–2005 (Preliminary)
12%
10%
8%
6%
4%
2%
0%
1962
1967
1972
1977
1982
1987
Total R&D/Total Budget
1992
1997
2002
Nondefense R&D/Total Budget
Note: Fiscal year 2005 data are budget proposals.
Source: American Association for the Advancement of Science 2005. Based on
Budget of the U.S. Fiscal Year 2005. Historical Table.
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This ratcheting in the magnitude of government funding reflects the effects of the
interplay between the machinations of the political process and justifications stemming from threats to national security, the desire to attain top-shelf world ranking in
(nondefense) basic research, and, more recently, post-9/11 antiterrorist R&D funding.11 But whatever the perceived immediate need (real and otherwise) or political
pressure used to justify government funding of science, a set of arguments exists
behind the screen that claims to establish a general theoretical justification for such
funding. We turn next to a critical examination of these arguments.
Rationales for Government Funding
The principal theoretical justification for government involvement in funding and
directing the activities of scientists and the dissemination of scientific knowledge rests
on a “market failure” argument, which claims that the characteristics of scientific
knowledge are such that it will be produced in suboptimal quantities without intervention.12 Nelson (1959) and Arrow (1962) offer the classic statements of this argument; Dasgupta and David (1994) have restated and augmented it more recently.13
Taking the classic and the modern treatments in turn, we show their theoretical basis
to be surprisingly weak and their empirical support to be conspicuously lacking.
Our major criticism, however, is that these authors, in concentrating on the “simple
economics” (and on sociology, in Dasgupta and David’s case) of scientific research,
ignore the political economy of government funding arrangements and their effects
on the system that generates scientific knowledge.
Nelson suggests that in a regime of nonintervention, underinvestment in basic
research would occur of necessity, largely because of “the classic external-economy
problem” (1959, 306).14 Firms other than the one conducting the research can benefit
11. Budget appropriations to combat terrorism have been one of the fastest-growing aspects of federal
R&D funding. For example, from fiscal year 2002 to 2003, appropriations for counterterrorism activities by various agencies, including Defense, Health and Human Services, National Institutes of Health,
Environmental Protection, and Justice increased from $1.2 billion to $2.9 billion (National Science Board
2004a, 4.28 and 4.29). Subsequent budgets (since the creation of the Department of Homeland Security
in January 2003) have not separated counterterrorism R&D from other R&D programs.
12. Of course, within the context of neoclassical economic analysis, “the observation of external effects,
taken alone, cannot provide a basis for judgment concerning the desirability of some modification in an
existing state of affairs. There is not a prima facie case for intervention in all cases where an externality is
presumed to exist. The internal benefits from carrying out the activity, net of costs, may be greater than the
external damage that is imposed on other parties” (Buchanan and Stubblebine 1962, 381).
13. Many commentators on the economics of scientific research, in addition to Dasgupta and David (1994),
are indebted to Nelson and Arrow for various aspects of their analysis. See, for example, Radnitzky 1986;
Diamond 1988; Brock and Durlauf 1999; many of the papers republished in Mirowski and Sent 2002; and
a series of papers summed up in Ziman 2002. We do not deal here with treatments of science that explicitly
represent science as a type of market. The most thoughtful of these treatments is Walstad 2002; for an
analysis and criticism of the analogy, see McQuade forthcoming.
14. Nelson allows that “the profit motive may stimulate private industry to spend an amount on applied
research reasonably close to the amount that is socially desirable” (1959, 305). His characterization of applied
research, in contrast to basic research, is one of a matter of degree: research is more basic to the extent that
“the degree of uncertainty about the results . . . increases, and the goals become less clearly defined and less
closely tied to the solution of a specific practical problem or the creation of a practical object” (300).
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from the results, but the generating firm’s ability to internalize that value by patenting
is severely limited.15 Further, the inability to appropriate their results effectively leaves
the firms with the option of keeping the results secret, but this practice is inefficient
from a societal perspective, owing to the public-good nature of knowledge. As Nelson
puts it, the “marginal social cost of using knowledge that already exists is zero” (306),
so whereas free access to all knowledge generated is optimal from a societal point of
view, such is not the case from the generating firm’s point of view. To mandate a common pool for all basic research generated by private firms would reduce the incentive for
knowledge production in the first place. Nelson concludes, then, that publicly funded,
industry-independent research institutes and universities are the preferred organizations
for conducting basic research because “were the field of basic research left exclusively to
private firms operating independently of each other and selling in competitive markets,
profit incentives would not draw so large a quantity of resources to basic research as is
socially desirable” (Nelson 1959, 304). Moreover, because private firms (presumably
operating at the point where expected marginal revenue is equal to marginal cost) do
in fact conduct some basic research in the face of reduced incentives, this activity is an
indication that the current funding of public research is less than optimal.
Arrow elaborates on Nelson’s arguments, highlighting the inherent riskiness of
research, the indivisibility of its product, and the lack of appropriability of the product’s value as sources of inefficiency in a free-market environment that government
intervention can ameliorate. The problem of risk is straightforward: “Since [invention] is a risky process, there is bound to be [on the part of risk-averse individuals]
some discrimination against investment in inventive and research activities” (1962,
616). Arrangements for shifting the risk, including insurance, are incomplete or
have optimality problems of their own. Therefore, as the solution to this problem,
he posits “government or some other agency not governed by profit-and-loss criteria” and capable of risk neutrality (619). The problems of indivisibility and lack of
appropriability are simply the public-goods problem discussed earlier, and Arrow,
following Nelson, concludes that in “a free enterprise economy, inventive activity is
supported by using the invention to create property rights; precisely to the extent
that this is successful, there is an underutilization of the information” (615).
Setting aside for the moment the political economy of government intervention
in science, the economics of the Nelson and Arrow analysis has three fundamental
problems:
First, their underlying model of the processes of knowledge generation, appropriation, and utilization is institutionally inadequate. In fact, for the case of a private
firm, no process is envisaged that differs in principle from that of making, selling, or
15. Nelson also suggests two other factors that reduce the incentive for private firms to pursue basic
research: “the long lag that very often occurs between the initiation of a basic research project and the creation of something of marketable value” and “the very large variance of the profit probability distribution
from a basic research project” (1959, 304).
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using a commercially useful good. The good in question is simply problematic from
the point of view of the profit-seeking firm because of uncertainty in production, difficulties in appropriation, and indivisibilities in consumption.16 No account is taken
of the more complex arrangements in which firms can and do hire scientists, encouraging them to conduct basic research and to publish the results freely, expecting
that this activity will enable them to learn about and make use of published research
appropriate to the firm’s narrower production goals.17 And no account is taken of the
fact that scientific knowledge is in general not like a simple “recipe” or “blueprint”
that can be put to immediate use.18 To understand it, let alone to utilize it profitably,
requires both entrepreneurial insight and a considerable investment in acquiring and
maintaining the requisite background knowledge. In short, scientific knowledge has
a tacit component that cannot be conveyed easily, which renders published scientific
information, though necessary, insufficient for garnering free-rider profits.19
Kealey’s analysis is particularly instructive here (1996, 225–30). It is based, first, on
identifying two kinds of advantages associated with basic research and, second, on recognizing some pertinent institutional detail about firms, scientists, and R&D. Basic science,
says Kealey, confers “first-mover advantages” on a company when it discovers something first. This kind of advantage may position the company farther along the learning
curve in developing the discovery’s commercial applications. At the same time, though,
if companies derived only first-mover advantages from basic research (as Nelson and
Arrow assume), such research would be unlikely to enjoy widespread commercial support because basic science is commercially unpredictable. “Second-mover advantages,”
in contrast, derive from a company’s ability to generate commercial applications of existing basic research; these kinds of advantages are less risky and more profitable than basic
research.20 As Kealey observes, “first- and second-mover advantages are indissolubly
16. Even if these characterizations of knowledge are taken at face value, the presumed incentive effects
do not necessarily follow. As Rosenberg argues, the “mere existence” of uncaptured benefits “is never an
adequate explanation for the reluctance to perform basic research” (1990, 167, emphasis in original),
provided the firm can capture sufficient benefits from its research. Even though the research may generate
spillovers, it is not their magnitude that matters, but the return on investment the firm is likely to realize
from derivative commercial applications.
17. Rosenberg (1990) reports that firms fund basic research because it generates cross-fertilization of ideas,
problem solving, and creativity among scientists and other company employees. Hicks (1995) observes
that firms find it in their interest to hire freely publishing research scientists for a variety of reasons: such an
employment practice provides access to research networks, keeps their scientists engaged and up-to-date,
and presents an image in the academic and scientific community conducive to recruitment.
18. On this point, see Pavitt 1987 and Rosenberg 1990.
19. Dasgupta and David appear to disagree, saying that they “find no compelling grounds for associating
the tacit knowledge of either technologists or scientists necessarily with skills that are specific rather than
‘generic’ in their applicability” (1994, 494). But simply to say that “the boundary between the codified
information and tacit knowledge in a specific field of scientific research may be shifted endogenously by
economic considerations” (495) does not do away with the disincentive of the cost of actually acquiring the
skills, especially given that the particular skills needed may not be predictable in advance.
20. Kealey (1996) reports on a 1992 study of Japanese pharmaceutical firms by Odagiri and Murakimi that
found rates of return from basic research and “second-mover” research to be 19 percent and 33 percent,
respectively.
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linked, and one cannot be performed without the other. . . . [Thus,] second-mover
advantages enforce a vast expenditure on basic science” (1996, 229).
Second, Nelson’s and Arrow’s analyses of what set of institutional arrangements
for managing the activity of basic science would be more efficient than the autistic
“market” arrangements they model commit what Demsetz calls “the nirvana fallacy”
(1969, 1). A model of a supposedly realistic institutional arrangement is analyzed and
found to be suboptimal relative to an idealized arrangement whose possible shortcomings are not analyzed. As Demsetz puts it,
Arrow compares the workings of a capitalistic system with a Pareto norm
that lends itself to static analysis of allocation but, nonetheless, that is
poorly designed for analyzing dynamic problems of production. He finds
the capitalistic system defective. The socialist ideal, however, resolves static
allocation problems rather neatly. But this is only because all the dynamic
problems of production are ignored. The comparison of a real capitalistic
system with an ideal socialist system that ignores important problems is not
a promising way to shed light on how to design institutional arrangements
for the production and distribution of knowledge. (1969, 12)
On the matter of the riskiness of basic research, for example, it is quite invalid
to assume that the risk-averse actors populating the “free-market arrangements”
model would be replaced by risk-neutral actors in the “ideal arrangements” model.
And questions of “underutilization” presume an ability to determine, under the
ideal arrangements, what quantity and direction of research to pursue for maximum
utilization—a dubious assumption at best.21
Third, Nelson and Arrow assume without analysis that the only adequate source of
funding for basic research is the government.22 The empirical record shows, however,
that private sources consistently commit substantial sums to basic research as well as to
R&D.23 As shown in figure 4, basic research by firms accounts for approximately $8
billion to $10 billion per year. Other nonfederal sources of funding for basic research—
which include nonprofit organizations, universities, and state governments—brought
21. These issues are discussed in detail in Demsetz 1969. Although we endorse Demsetz’s criticisms of
Arrow (1962), we have reservations about some of his suggested solutions. For example, we do not see that
the creation of property rights in basic scientific results is a reasonable or viable arrangement. (We should
be clear here that we do see the viability and desirability of the appropriation of services that enable the
dissemination and use of basic scientific discoveries. For example, the base sequence of the human genetic
code is a scientific discovery published openly and owned by nobody, but the database containing this code
and allowing access to tools for gene search and identification is the property of its developer.) Also, see
Walstad 2002, 25, for a sensible critique of treating research contributions as “intellectual property.”
22. No indication is given as to how one would actually determine the marginal social return for a research
project in order to contrast this return with the (equally indeterminate) social opportunity costs of activities
forgone owing to the government’s extraction of the funds from the public.
23. They do so because they expect the action to be profitable. Mansfield (1980) estimates an implicit
rate of return of 27 percent on total R&D (1960–76) for chemical and petroleum firms. He finds a strong
independent relationship between basic research and productivity; however, that finding may “reflect
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Figure 4
U.S. Basic Research Expenditure, by Funding Source, 1991–2003
(billions of 2003 dollars)
60
50
All Other Sources*
40
Industry
30
Total Federal
20
*State and local government,
nonprofits, and colleges and
universities (own funds)
10
2004
2003
2002
2001
2000
1999
1998
1997
1996
1995
1994
1993
1992
1991
0
Source: American Association for the Advancement of Science 2006d. Based on NSF,
National Patterns of R & D Resources: 2005b.
the total to more than $20 billion in 2003, or approximately 40 percent of the total
funding for basic research. For total R&D expenditures by source, the data reveal that
industry has allocated increasingly significant resources toward R&D. As seen in table 1,
total industry-funded R&D expenditure since 1980 has exceeded federal R&D expenditure and is now (according to data for 2003) nearly twice as great.
Whether the amounts of basic science and total R&D expenditures undertaken
by the private sector are “optimal” survives only as a model-dependent question and
lacks empirical content. Indeed, the standard neoclassical argument assesses optimality across only the quantity dimension. More is always better. Because the argument
cannot rule out utterly perverse kinds of scientific research funding, it implicitly requires a second-order criterion for the allocation of research funds that must
emanate from a political process.24 Once account is taken of this political element,
a tendency for basic research findings to be exploited more fully by industries and firms responsible for
them” ( 871). He suggests that basic research may be a proxy for long-term applied R&D (866). Griliches
finds that R&D, especially basic research, and the fraction of research financed privately (versus federally)
contribute positively to productivity growth. According to his estimates, “raising the stock of R&R by
20 percent but shifting it all into the private component doubles the effect of such dollars” (1986, 149).
Interestingly, he acknowledges that such results may be flawed because R&D often aims at creating new
products as opposed to increasing productivity. He finds that firms tend to capture high returns from basic
research, even if it is assumed that 50 percent of the positive effects of basic research are diffused throughout
the industry. Working with data for the years from 1967 to 1977, Griliches (1987) also shows that dollar
for dollar, industry-financed basic research contributed far more to economic growth than did governmentfinanced basic research. Kealey claims that these findings support the notion that private companies “fund
basic science comprehensively” and that this practice is “highly profitable” (1996, 225).
24. For example, scientific tests of radiation exposure on U.S. servicemen and prison inmates during the
1950s.
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Table 1
National Funds for R&D, by Source, 1970–2003 (millions of 2003 dollars)
Percent Share of Total
1970 1980 1990 2003
Actual Actual Actual Prelim. 1970 1980 1990 2003
Federal
57,801
58,909
79,831
85,279
57.0%
47.4%
40.5%
30.0%
Industry
40,307
60,784 107,821 179,615
39.8%
48.9%
54.7%
63.3%
Colleges
and Univs.
999
1,808
4,130
7,944
1.0%
1.5%
2.1%
2.8%
State/Local
914
1,020
1,813
2,710
0.9%
0.8%
0.9%
1.0%
1,323
1,712
3,355
8,247
1.3%
1.4%
1.7%
2.9%
Nonprofits
TOTAL
101,341 124,232 196,949 283,795 100.0% 100.0% 100.0% 100.0%
Source: American Association for the Advancement of Science 2004b. Based on data from the
Division of Science Resources Statistics, National Science Foundation.
the presumed “optimality” argument is underdetermined. In short, all that can actually be said is that the private sector, of its own choice, does undertake the funding of
significant amounts of both basic research and R&D.
In the standard market-failure argument, no account is taken of the possibility,
discussed by Martino (1992, chap. 27), that a side effect of government funding of
science has been the driving out of funding contributions from private foundations and
endowments, rich private donors, and the general public. No evidence is presented to
support the assumption that these sources of funding would simply remain at their current levels were government funding to be significantly reduced or eliminated. In addition to the opportunities for reputational enhancement (individual or institutional)
and even for immortality that funding of a selected institution, research project, or
individual scientist might present, science has popular appeal as a societal “good” and
is unlikely to be left seriously impoverished by a retreat of government intervention.
Dasgupta and David (1994) restate the Nelson-Arrow economics of science
and augment it significantly by taking into account the particulars of the different institutional arrangements through which scientific and technical knowledge is
generated. They distinguish sharply between “open science” (the research arrangements characteristic of universities and of nonprofit or government research institutes in which the reputation-based reward system works to hasten both discovery
and its disclosure) and commercial R&D, or “technology,” in which the reward
system is oriented to material benefit and the desire for profit is not conducive
to open disclosure. They do not advocate one of these arrangements over the other:
although “it is evident from the contradictory norms on which they are based that
there is a tension between these two modes of economic and social organization, so
that they do not ‘mix’ easily, the two are not mutually exclusive ways to successfully
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organize the pursuit of scientific knowledge within the same society” (498). In fact,
given that both modes are operative in modern society, the relevant policy problem is
to “attend to maintaining a synergetic equilibrium between them” (498).
This is not to say that no “inefficiencies” exist in each of the two knowledge-production arrangements. Dasgupta and David point to problems in technological knowledge
markets, including thinness (and therefore lack of efficient pricing),25 leakage (owing to
the inevitable disclosures that must be made in a sales situation), and underutilization on
a societal basis (echoing Nelson and Arrow) (496–97). These problems can be offset in
large part, but certainly not completely, by patenting, secrecy, and the incentive provided
by the anticipation of monopoly profits.26 Open science, they say, has problems of rivalry
(which can weaken the incentive to prompt disclosure), resource allocation (in which the
“all-or-nothing” aspect of the priority-based reward structure encourages the selection of
research projects that are unduly risky or overly similar and leads “to the possible neglect
of other areas in which the entry of even a few competitors might be socially beneficial”),
and timing (the difficulty of achieving optimal sequencing of projects in a decentralized
arrangement) (500–501, 505–10). These problems, they allege, can be dealt with, at
least partially, by the diligence of public funding agencies.27
The main conclusion emphasized by Dasgupta and David is the policy point,
noted earlier, that these two modes of knowledge generation, each adequate
(if not perfectly optimal) in its own environment, need to be maintained “in dynamic
balance” (510). Firms benefit from the results of open science (not necessarily immediately, but eventually) and from its training and certification of researchers, and this
benefit redounds to society: “the important economic payoffs to society from basic
research come in the form of higher rates of return on expenditures allocated to
applied research” (510).28 They assert that this “science-technology nexus” must be
maintained by government funding and offer a stark warning of the consequences of
25. Also see Arrow 1971.
26. The existence of monopoly profits would indicate an inefficiency, however, at least relative to a Pareto
ideal.
27. In this context, peer review is widely regarded as a vital mechanism for ensuring a rational allocation
of public funding. But see Martino 1992, chapter 5, for a discussion of its strengths, limitations, and
inherent problems. However, given that there is to be public funding, with its inevitable conflict between
expert judgment and public accountability, then peer review seems as good a mechanism as any relative
to the alternatives (bureaucratic selection, selection by political influence, and formulaic selection such as
seniority—all of which have that conflict).
28. Dasgupta and David do not make the mistake of subscribing to the simplistic and unidirectional “linear
model” in which investments in basic science lead directly to economic growth via technological change.
This model of economic development through science was recognized as defunct on scientific grounds in
the 1960s, although it lives on for political purposes. Its proponents argue that without the appropriate
amount of basic research, technological innovations and material progress will lag, and the government
must provide the funding necessary to sustain an adequate amount of basic research and thus to promote
economic growth. The basic error in the model (apart from the assumption of the necessity of government
provision of funding) is the claim that new basic science drives technological change. Existing science and
existing technology, however, have been found to cause technological change. For more discussion on
this topic, see Kealey 1996, 204–5; Greenberg [1967] 1999, 29–30; Martin and Nightingale 2000; and
Feldman, Link, and Siegel 2002, 17.
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doing otherwise: “Under conditions approaching the state of ‘universally privatized
science’ that such ideologues [that is, ‘conservative’ policy commentators] call for, an
unbalanced research regime might continue to generate economic growth through the
exploitation of the scientific and technological knowledge base, but sooner or later,
economic progress almost certainly would lose the sustained character that has been
taken by many scholars to distinguish ours from previous historical epochs” (515).
They present no evidence for this claim, however.29
Although Dasgupta and David’s introduction of real-world institutional considerations into the economics of science is a welcome advance, we find the following
deficiencies in their argument for government involvement in the funding of science.
First, they add nothing to the basic Nelson-Arrow assertion, criticized previously,
that private funding would turn out to be inadequate were government removed as a
source of funding. In contrast to the scenario described in the passage just quoted, it
is not credible that the advance of basic science, important in the long run to technological development, would slow to an extent that would have a marked effect on economic well-being. Our skepticism does not reflect a blind faith in the workings of the
market—we have no truck with the pronouncements of policy pundits, conservative or
otherwise—but rather an appraisal of the many possible motives, not limited to profit
seeking, for supporting open science in the absence of government intervention and for
maintaining the operation of the productive “science-technology nexus.”30
Second, they assume that basic science performed in a private funding environment
would not be published openly (at least not without a considerable delay), but rather
would be conducted in secrecy to guard against exploitation by competitors. There is
no reason for such secrecy to prevail with private nonprofit funding, however, and even
for science funded internally by profit-seeking firms, secrecy is not necessarily the best
strategy, as our previous discussion of “second-mover advantages” makes clear.
Third, their insistence on the importance of government funding to the continuing growth of basic science, together with the downstream importance of the application of earlier basic science for economic growth, suggests that the massive increase in
government funding of science immediately after World War II would show up sooner
or later as a discontinuity in the pattern of economic growth. Yet, more than fifty years
later, no such discontinuity has occurred. No significant correlation can be seen between
the amount of federal expenditure on basic science and the trend in GDP per capita, as
documented by Kealey (1996, 162) for the nineteenth and twentieth centuries.
29. David (1997), in a very critical review of Kealey 1996, maintains that private R&D funding is no substitute for public funding, and he disputes Kealey’s finding that government funding crowds out private
funding. Suffice it to say that the statistical evidence that can be gleaned in an environment of heavy government funding is inconclusive and probably subject to a variety of interpretations. Our appraisal of the
institutional structures at play and the incentives they embody, however, leads us to suspect that Kealey is
closer to the truth.
30. Such motives include, in addition to profit seeking, the usual motives of private donors (which range
from a sense of civic duty to a desire for immortality by association) and the institutionalized motives of
foundations and trusts.
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Fourth, they do not extend their real-world institutional analysis to encompass
the government funding mechanisms themselves. Although they allude to the possibility of commonalities with some areas of public economics (1994, 510), they do not
consider the particular incentives characteristic of government funding agencies, such
as those documented by Martino (1992), which manifest themselves in favoritism,
scientific conservatism, and pork-barrel spending. In the absence of any serious institutional analysis in this area, one is left with a “public-interest” picture of government
that, in the face of public-choice skepticism, requires for credibility specific attention
to any mechanisms that might turn the normal self-interest of politicians and funding
agency bureaucrats to the service of some concept of public interest.
Our conclusion is thus that the economic justification for government funding of
science is (1) theoretically unconvincing because it ignores institutional arrangements
within firms that negate the force of the “market failure” arguments and because it does
not account for the institutional realities of political and bureaucratic funding agencies,
and (2) empirically suspect because it ignores the substantial evidence of the robustness
of the private provision of scientific knowledge and because it predicts that increased
government funding above trend would (with an unspecified lag) result in increased
economic growth above trend, a putative link for which no solid evidence exists.
Nevertheless, the extent of government engagement in science has trended
upward for decades. This trend suggests that the forces driving the increase have
more to do with a confluence of interest between politicians and scientists—a dynamic
investigated in some detail by several scholars, including Martino (1992), Savage
(1999), and Greenberg ([1967] 1999, 2001).31
An Analysis of Science Interventionism
The evolution of government policy with regard to science since World War II is best
understood as a variant of an interventionist system rather than as a system of benign,
decentralized support imagined by Vannevar Bush and others. Further, although the U.S.
government’s current role in science is not technically that of a central planner, many of
the considerations that apply to centrally planned economic systems also apply in some
degree to the ongoing arrangements between government and science in this country.32
31. Greenberg’s (2001) work is especially enlightening. He describes in detail the history of the increasing
entanglement of science and politics in the United States from World War II to the present: the enormous
growth in government funding of the physical and biological sciences; the ways in which scientists and
their universities have operated to claim and foster the increase of that largesse; the surprisingly unscientific,
but politically effective propositions they have promoted to justify their right to public funding on a large
scale; and the practical political reasons why legislators are likely to have the incentive to go along with the
arrangement. He sees scientists as having succeeded beyond their wildest dreams in extracting public funds
for their own use, but cautions that this activity has come at the expense of “the ethics of science.” According
to Greenberg, access to funding is surpassing reputation as a motivating force in science, a change that has
led to an undermining of collegiality and, in some cases, honesty within science. As he sees the situation, the
traditional standards of science have been corrupted by decades of misleading representations to the public
and the government in pursuit of public money.
32. See Ikeda 1997 for a similar argument in the context of government-market interactions.
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In the absence of outside intervention, science is a decentralized system of social
interaction that operates according to generally understood rules associated with the
institutions of publication and citation (McQuade and Butos 2003). There is no controlling authority because power is distributed (not necessarily evenly, but still widely)
across the population of participants. The institutional arrangements of science explicitly cater to all participants’ self-interest. The process of interaction constrained by
these arrangements results in observable side effects stabilized by negative feedback:
the corpus of scientific knowledge and participating scientists’ generally acknowledged
reputations. This stabilization, however, does not preclude variation of the side effects
in response to environmental changes, and these relatively stable side effects provide
not only general and nondiscriminatory benefits even to nonparticipants, but also the
incentive for a positive feedback effect on participation in the system.
Science in and of itself generates no revenue, so the expenses associated with scientific pursuits must be funded by other sources.33 Because few scientists are independently
wealthy, they are commonly employed as teachers in academic institutions, receiving
both a salary for personal maintenance and some financial support for the operational
expenses of their scientific activity. They may also receive support directly from private donors or corporations,34 and they may be financed by grants of public funds.
It is not surprising that these different funding sources should have different effects on
the practice of science. Examination of such effects leads directly to a consideration of
intervention in science, for it is through funding that organizations outside of science
can most easily affect scientists’ actions, introduce new incentives, exercise control, and
alter the adaptive characteristics of the knowledge-generating system as a whole.
The three broad sources of outside funding (donors, businesses, and legislatures)
have an obvious similarity: in each case, the funding, or its continuation, has strings
attached. Donors may be motivated by civic duty or by a desire for the immortality of
association with a fundamental advance or a large institution; businesses by the indirect
profitability of such funding; and legislators by the benefits that the expenditure of the
funds produces in their districts or by the enhancement to their reelection prospects
associated with their promotion of a good and popular cause. The first two source types
33. We treat science as a distinguishable social process—the publication/citation regime—that clearly does
not involve monetary exchange and hence revenue. We do not deny that, in practice, science is embedded
in the market and depends on market-generated revenue for the maintenance of the people involved. Nor
do we deny that aspects of scientific knowledge (or even aspects of the individual knowledge of a particular
researcher) can be marketed (even patented) by organizations such as corporations and universities that
employ scientists.
34. People who work for corporations or government departments engaged in research that is not openly
published are not participating in science as defined here. (Or, they may be doing so on a small scale, limited to the confines of their organization, if they circulate papers and cite the work of others within their
local circle.) Such organizations, however, often do employ scientists and pay them a salary while allowing them to publish in the usual scientific outlets. We do not deny that a researcher who does not publish
may be doing “science” in the sense of doing some of the things that one expects scientists to do—for
example, experimenting, thinking, and formulating hypotheses—but in order to affect scientific knowledge,
a contribution must be published in some form. Only published contributions can be assessed, criticized,
interpreted, reinterpreted, and recontextualized—that is, submitted to the process of becoming absorbed
into scientific knowledge.
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have constraints more or less tied to the scientific results produced. The third, however,
measures success not necessarily by the science produced, but by the perception among
voters and constituents that they themselves might benefit from the particular funding. For government funding, the funding constraints are therefore much less pressing
(the amounts potentially available through government taxation, borrowing, or money
creation are huge), and they are the least connected with the success (in terms of usefulness to other scientists in follow-on research) of the scientific activity itself. These
characteristics, compounded by the organization of the government funding apparatus
into a small number of large bureaucracies, have potentially corrosive effects in several
ways. We divide these effects, for ease of exposition, into incentive effects, “Big Player”
effects, problems of boom and bust, and problems of bureaucracy.
Incentive Effects
Under government science, incentives matter, just as they do in markets. These incentives will affect the institutions involved in the administration of science, including
funding agencies’ recipient institutions, and also affect how scientists behave. Funding
agencies are not autonomous, but operate as bureaucracies in the government. Their
incentives emanate, at least in part, from the legislative and the executive branches,
thereby establishing a political dynamic for explaining their behavior along any
number of margins, including the areas of science that receive funds, the institutional recipients, and the patterns of geographic disbursement. Symmetry of interests
exists between the funding agencies, including the military, and recipient institutions
(industry and universities), which has implications for the dynamics of government
science because it creates a potentially powerful lobbying nexus of parties whose interests are geared to sustaining and expanding government funding (Ikeda 1997).
A well-known example of such lobbying occurs in academic “earmarking”:
“a legislative provision that designates special consideration, treatment, funding, or
rules for federal agencies or beneficiaries” (Savage 1999, 6). Academic institutions
use their influence and lobbyists to secure appropriations for specific (“earmarked”)
university research projects or facilities. As table 2 shows, such funds averaged about
$550 million per year during the 1990s and had tripled by 2002.
The enormous growth in academic earmarked funds reflects the increasingly
significant influence of academic institutions in securing federal funding. As seen
in figure 5, the growth in federal funding is principally accounted for by the funds
allocated to academic institutions. In 2002, federal funds directed to academic
institutions exceeded $22 billion. In addition, of the $11.5 billion allocated to
federally funded R&D centers (FFRDCs), more than $7 billion went to the sixteen
university-administered centers.35
35. NSF 2005b, table B-15, pp. 86–87. FFRDCs include such well-known facilities as Los Alamos National
Laboratory (University of California), Jet Propulsion Laboratory (California Institute of Technology),
Lawrence Livermore National Laboratory (University of California), and Argonne National Laboratory
(University of Chicago). These four account for more than $5 billion of the $7 billion total.
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Table 2
Funds for Congressionally Earmarked Academic Research
Projects, 1980–2002 (millions of current dollars)
Year
Amount
Year
Amount
Year
Amount
Year
Amount
1980
11
1986
111
1992
708
1998
528
1981
0
1987
163
1993
763
1999
797
1982
9
1988
232
1994
651
2000
1,044
1983
77
1989
299
1995
600
2001
1,668
1984
39
1990
248
1996
296
2002
1,837
1985
104
1991
470
1997
440
Source: National Science Board 2004a, 5–16.
Figure 5
Federal R&D Funding, by Type of Performer, 1970–2004
(billions of 2004 dollars)
30
25
All Other
20
FFRDCs
15
Univs & Colleges
10
Industry
5
Federal
0
1970
1975
1980
1985
1990
1995
2000
2005
Source: Association for the Advancement of Science 2004a. Based on NSF, Federal
Funds for Research and Development Fiscal Years 2002. 2003. 2004 and Federal Funds
Historical Tables. 2004.
A closer look at R&D expenditures at academic institutions for 2001 and 2002
shows that 67 percent of the total funds originated from federal, state, and local government (see table 3). Funding sources from academic institutions themselves accounted
for nearly 20 percent of the total amount, and industry and other sources (principally
nonprofit institutions) accounted for 6 percent and 7.4 percent, respectively. Most of
these funds (59 percent) went toward research in the life sciences; the next largest allocations went to engineering (15 percent) and the physical sciences (8 percent).
Data on the use of funds by academic institutions from 1973 to 2004 show that
the amounts for R&D in engineering, the physical sciences, environmental science,
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Table 3
R&D Expenditures of Academic Institutions, 2001 and 2002
FY 2001 FY 2002
% Change % of Total
FY 01-02 (FY 02)
R&D expenditures
in millions of dollars
by funding source
Federal Government
19,213
21,834
13.6%
60.1%
State and Local Government
2,316
2,501
8.0%
6.9%
Industry
2,214
2,188
-1.2%
6.0%
Institutional Funds
6,587
7,109
7.9%
19.6%
All Other Sources
2,438
2,701
10.8%
7.4%
32,767
36,333
10.9%
100.0%
Engineering
5,007
5,504
9.9%
15.1%
Physical Sciences
2,805
3,008
7.3%
8.3%
Environmental Sciences
1,830
2,022
10.5%
5.6%
Mathematical Sciences
359
387
7.8%
1.1%
Computer Sciences
954
1,126
18.0%
3.1%
19,213
21,404
11.4%
58.9%
583
671
15.1%
1.8%
1,440
1,583
9.9%
4.4%
577
627
8.8%
1.7%
32,767
36,333
10.9%
100.0%
24,273
26,959
11.1%
74.2%
8,494
9,374
10.4%
25.8%
32,767
36,333
10.9%
100.0%
Total
by science and engineering field
Life Sciences
Psychology
Social Sciences
Other Sciences, n.e.c.
Total
by character of work
Basic Research
Applied Research and
Development
Total
Source: NSF 2004, table 1-8, p. 58.
mathematics and computer science, psychology, and the social sciences have been
rather stable over those thirty years. In contrast, the increase in R&D funding for the
life sciences has been nearly sixfold. Figure 6 displays these trends.
Academic institutions’ obvious success in securing substantial government assistance reflects a strengthening “partnership” between them and government funders.
Although this development is justified in part on the grounds that nearly 75 percent
of the R&D performed at academic institutions is “basic research,” it also suggests
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Figure 6
Federal Academic Funding Obligations, by Discipline, 1973–2004
(billions of 2004 dollars)
$15
Life Sciences
Engineering
Physical Sciences
$10
Environmental Sciences.
Math/Comp. Sciences.
Social Sciences
$5
$0
1973
Psychology
Other*
*Includes research not elsewhere classified.
Data exclude development and R&D facilities.
1978
1983
1988
1993
1998
2003
Source: American Association for the Advancement of Science 2006b. Based on NSF,
Federal Funds for Research and Development, 2004.
that the direction and character of university science have become increasingly intertwined with government-determined priorities and oversight.
Scientists’ success in securing funding testifies to their submission of proposals
that receive a favorable hearing by the funding agencies. Thus, scientists have an
incentive to develop and nurture professional relationships with agency members,
advisors, and consultants. Finally, government funding of science, including that
associated with military R&D, unavoidably establishes linkages between the funding
agencies’ preferences (or legislative charge) and the scientific activity that university
and industry researchers perform. These linkages relate to the purposes for which
funds are made available, thereby affecting the direction and regulation of scientific
research as well as specific protocols for military R&D.36 Greenberg (2001) does an
especially good job of documenting this complex of interlocking incentives.
The mechanisms that funding agencies use to disburse funds reveal the significance
of incentive effects. Although the earmarking of funds represents a somewhat peculiar
means of allocating them, we suspect that in all practicable cases some sort of competitive
or open solicitation of federal research monies occurs and that the method of selection
entails a peer review process. Such mechanisms presumably help to keep science “honest” and “open.” At the same time, however, the peer review process may entail certain
undesirable consequences. Martino (1992, chap. 5) suggests that a bias against lessprestigious schools may exist. In 1984, he notes, the top twenty institutions received 46
percent of NSF funds (and provided 25 percent of the peer reviewers) and 44 percent of
National Institutes of Health funds (with 30 percent of the reviewers). This distribution
36. Mukerji claims that the military directs classified research by controlling the scientists’ access to research
technology. Although scientists working for the military cannot publish their research, “they are able to get
access to restricted information for their own use” (1989, 116).
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does not prove bias, however, because the best researchers (in terms of citations) tend
to work at the most prestigious universities, so it would be no surprise if funds allotted
according to merit tended to favor these institutions. Nevertheless, even if peer review
works as advertised, the unintended result is to strengthen the paradigms, models, and
ways of thinking that currently characterize particular disciplines and distinguish the various disciplines from each other. This effect is an inherent by-product of having proposals
reviewed by experts in the scientific area of the proposal. Although outsiders may see
the peer review process as unfair, the implications of the process in terms of guiding the
direction of science are a far more significant issue.
“Big Player” Effects
The source structure of science funding matters: an environment with a small number
of large funders provides the potential for those who want to control the direction
(or, in the extreme, even the content) of science to have systemic effects, whereas an
environment with a large number of small funders more likely localizes and constrains
the effects of individually power-oriented operations. This funding situation is the
analog of the “Big Player” phenomenon in markets.
Following Koppl and Yeager (1996), we hold that government is a Big Player in
science whose behavior is capable of dominating the flow of signals guiding the direction and intensity of scientific research. The magnitude of government’s influence
exposes science to self-reinforcing path-dependent processes that may be analogous
to herding and bubbles in financial markets. However, unlike markets, where the
prospect of self-correction is strong because underlying market realities prevail sooner
or later, science has no analog of resource constraints for its products and has to rely
only on its internal coherence as established by its own critical procedures. Big Player
effects are known to produce herding and bubbles in financial markets. The corollary
in science is the funding opportunities government provides for designated areas of
research, such as AIDS or environmental issues.
Because such government-funded research enthusiasms are inextricably linked
to the political process, the presumption must be that the direction of research is
driven by the same incentives and constraints that drive other politically based funding
programs. This consideration suggests that the basis for such funding is arbitrary and
no more or less justifiable than any other possible use of taxpayer funds.37 Moreover,
the development of the direction of research itself is likely to be sustainable only for
as long as the funding continues, after which new funding objectives will replace
37. Consider, for example, government funding for breast cancer and lung cancer. Lung cancers are the
leading cause of cancer deaths in men and in women. Yet, since 2003, spending by the National Cancer
Institute of the U.S. National Institutes of Health (under the Department of Health and Human Services)
on breast cancer research, prevention, detection, and diagnosis has averaged $577 million per year, whereas
spending for lung cancer has averaged $286 million. The mortality rate per 100,000 from lung cancers
is more than twice that of the mortality rate from breast cancer. Even if these numbers were adjusted to
reflect lung cancers for nonsmokers, federal research funding per capita for breast cancer would still be
significantly higher. See National Cancer Institute 2005a and 2005b.
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previous ones.38 Government funding, in this sense, is not too unlike congressional
omnibus transportation bills: a predictable amount of funding will occur, but for what
and for whom is always up for grabs.
Problems of Boom and Bust
In recognizing that government science operates along a significant political dimension, we propose that the path of science also reflects the shifting funding priorities of
government institutions. The amount of government intervention in science can be
explained in part by public-choice considerations. Economists have long understood
that the economy’s cyclical activity or dynamic stability reflects the effects of central
bankers’ credit policies and perhaps representative democracies’ electoral cycles. In economics, we can think of fiscal policy’s effect on the average level of economic activity as
opposed to monetary policy’s effect on the system’s dynamic stability. In proposing a
similar kind of distinction for analyzing government intervention in science, our discussion considers such intervention in the context of the dynamic stability of science.
Windfall funding for science is like artificially cheap credit for business: the
immediate effect is a growth in investment (including employment) and, with a lag,
in output. The general quality of the output is not necessarily compromised, although
by making it possible for people who would otherwise work elsewhere to pursue a
scientific career, the tendency may be to lower the average quality of the practitioners.
What may be noticeable is an increase in the irrelevance of the investigations pursued,
in the sense that the resulting papers are of little or no interest to other researchers
and generate few, if any, citations and follow-on publications.
In the distribution of government science funding, one would expect to see
bursts of heavy funding in some areas, cutbacks or neglect in others, with the identities
of these areas changing as the political winds change direction.39 When the Russians
threaten to lead the way into space, astronautics and space science is favored in the
United States, building up an impressive edifice of research capability and trained scientists ready to push the discipline further. When the Japanese threaten to develop
a “fifth-generation” computer, attention in the United States switches to computer
science, and space-related science funding becomes insufficient to maintain the talent
already developed. When the Japanese are no longer seen as a danger to national prestige, political attention wanders away from computer science, and employment for
38. We cannot discount the path dependencies that government-funded science will create. In the present
context, it is possible that the prior existence of funding will establish an ongoing presumption of the value
of continued funding in those previously designated areas on the basis of results that previous funding has
already achieved.
39. Such effects may be observable in changes in the spectrum of paper citations. A trend toward more
published papers that receive very low numbers (particularly zero) of citations might be correlated with
changes in funding amounts (specifically a lag). Zero-citation papers are the scientific analog of goods
produced in excess of consumer desires. One would expect a period of lavish funding to be followed by an
increase in the number of “useless” papers published and the reverse trend after funding downturns. Similar
trends might be observed in journal start-ups and closings.
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newer Ph.D. holders in the area of research for which they have been trained is much
harder to come by than they had expected it to be. The scenario is one of localized
booms and busts—“science cycles”—accompanied by the disruption of individual lives
and the waste of talent and resources similar to that characteristic of business cycles.
Thus, temporarily unconstrained funding fosters unstable growth. Lavish funding results in more scientists being trained because the recipients of funds require
assistants to pursue the funded projects; in turn, these assistants, if they are to become
researchers in their own right, will require funding of their own.40 Private funding
sources, in contrast, naturally limit the growth of the system of science in a way that
has a relatively direct connection to the perceived usefulness of the science itself to
other scientists, and this sort of stabilized growth is likely to be more durable and productive than spurts of growth and retrenchment based on factors external to science.
The risk to quality of output and integrity of behavior comes with the downturns
in funding, when the rate of increase of funding ceases to keep pace with the structural growth fostered by prior funding. Then, scientists compete with each other not
merely for scientific reputation, but for their very livelihood.41
Problems of Bureaucracy
Concentration of funding in large government-financed organizations brings to
bear the usual symptoms of bureaucracy: success measured by budget rather than by
results, unwillingness to take risks that might subject the organization and its managers to criticism, and concentration on areas of research likely to be politically popular.
As Greenberg (2001) notes, bureaucratic control of the funding process has led to
conservatism (he calls it “calcification”). Although this result may not affect the general quality of research work, it tends to channel scientists who are seeking funding into more conservative, more obviously “acceptable” lines of inquiry and makes
funding for mavericks more difficult.
Underlying many of these untoward effects is the classic “knowledge problem.”
As formulated by Hayek, this problem arises because centralized institutional arrangements make it impossible for planners to marshal adequately the relevant explicit and
tacit knowledge dispersed among economic agents, leaving the planners limited largely
40. Changes in the number of trained scientists unable to find employment as scientists might be correlated
with changes in the amount of funding. One would expect to find unemployment trends in particular
areas within science characteristic of economic boom and bust. Even if science funding never decreased
absolutely, unemployment increases should be observed after a slowing of the rate of increase below that
required to fund adequately the new scientists who are minted in times of plenty. Because politically motivated funding tends to concentrate on particular areas of current political attraction, the analysis would
have to be at the level of the discipline or subdiscipline.
41. Although this outcome may be exceedingly difficult to document, reports of erosion of “scientific
ethics” should increase during scientific funding recession and should decrease during scientific boom.
Increases in “unethical” behavior driven by competition for funds would be the science analog of a scramble
for loans at the height of a boom as business firms strive to complete projects in the face of resource scarcity
or credit hardening. For a more standard economic discussion of fraud in science, see Wible 1998.
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to their own personal knowledge in determining the allocation of resources.42 As
Hayek (1937, 1945) reminds us, it is precisely the knowledge peculiar to time, place,
and circumstance, possessed by individual market participants but generating, via market interaction, a unique by-product—a constellation of market prices—that allows
agents to engage in a process of rational calculation in implementing their plans.
Although science is not a market and does not produce market prices, it nonetheless shares several characteristics with a catallaxy. First, science is characterized by a division of knowledge in that any individual scientist knows only a portion of the existing
knowledge in or germane to his own field. As scientific knowledge progresses overall,
each individual scientist knows relatively less, even as his own increasingly specialized
knowledge itself increases. Second, in the appropriate institutional setting, science has
the capacity to function as an unplanned, complexly organized order. Thus, like the catallaxy, it functions as an emergent order capable of generating novel outcomes that arise
as unintended by-products of the interactions among scientists. If we think of science
as generating warranted knowledge in the form of definitions, theories, and empirical
findings about reality, that knowledge is a snapshot of a mutable structure resulting from
an ongoing process of appraisement and absorption of the individual contributions of
past and current scientists.43 Although constrained by the procedures scientists deploy,
what emerges as scientific knowledge from the crucible of scientists’ individual work is
unplanned. Even if we may find it comforting to describe “truth” as an abstract goal of
scientific activity, the specific content of that goal is something that can be discovered
only as a by-product of the process itself. In this sense, science is end independent.
Attempts to plan science centrally, whether overtly or indirectly by monopolization of its funding, foster an institutional framework incompatible with science as a selfordering and self-correcting order.44 Planning’s implicit (and no doubt unintended) aim
is to remake science into a constructed order with particular ends specified in advance and
resources directed so as to achieve such ends or to serve special purposes. This objective
entails that government science tend toward dominating scientific activity both in terms
of the specific allocation of scientific manpower and capital and in terms of the specific
objectives that scientists seek to achieve. Underlying this tendency are two incorrect presumptions: first, that the planning board can somehow overcome the inherent division of
both explicit and tacitly held knowledge within the scientific community to organize and
direct science rationally, and, second, that in establishing specified goals for science and
directing scientific activity toward those purposes, the planning board will not subvert
the inherent discovery process associated with free science by reorienting science toward
the generation of preordained sorts of knowledge. Even if one were to concede that free
42. See the essays on the socialist calculation debate by Mises and Hayek in Hayek 1935. See Lavoie 1985
for a more recent treatment.
43. We have previously described this process in Hayekian terms as science generating a particular kind of
classification over some specified domain of inputs in order to capture the adaptive characteristics of various
knowledge-generating orders. See McQuade and Butos 2005; McQuade forthcoming.
44. See Hayek 1973, chap. 2, and Butos and Koppl 2003.
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science is subject to “market failure,” it does not follow that interventionist (and centrally
planned) science represents a coherent framework for correcting such putative failure.45
Another kind of knowledge problem also bears an equally and perhaps even
more important connection with science. At the very foundation of what science is
understood to be is the notion that it has the capacity to generate new knowledge.
The circumstances and conditions that induce the creation of knowledge are bound
up in the specific institutional arrangements that compose science and govern the
sorts of interactions in which scientists engage. As noted earlier, science is a particular
kind of order that generates as a by-product of scientists’ activities something we recognize as “scientific knowledge.” The principal characteristics of social orders such
as science are their dynamic stability and adaptability, which allow them to function
successfully as knowledge-generating systems. Yet, as we have seen, the structure of
government funding of science has adverse implications for long-term stability and
adaptability and therefore for the generation and use of scientific knowledge.
Conclusions
Government funding (and, by implication, its at least partial control) of science is widely
claimed to be an appropriate function of government. We have presented arguments
that dispute this claim. Valid analysis of science funding requires a perspective rooted
in the actual characteristics of scientific activity and its institutional arrangements and,
most important, in the characteristics of government funding activity and its institutional arrangements and their consequences. Our approach is geared to distinctions
that we believe are crucial for understanding the real world. The standard “science
as a public good” argument turns out on closer inspection to carry less significance
than the early work of Nelson, Arrow, and others suggests. As Martin and Nightingale
point out, work during the 1990s “has called into question many of the assumptions of the old economics of science, especially that science is a public good. . . .
What is now generally accepted is that the conventional ‘market failure’ justification for the public subsidy is weak” (2000, xxii).46 We find that the “new economics
of science,” though properly directing attention to the unique institutions of science, still falls back on the public-goods argument and on the uncritical acceptance of
government funding mechanisms as the only viable means of science funding.
By any metric, the role of the federal government in funding science is significant. For example, expenditures for R&D in the United States are estimated to have
been $276 billion in 2002.47 Of this amount, the federal government accounted for
45. Machan also associates government science with the problem of rational allocation under central
planning (2002, xiii–xx).
46. It is significant that Martin and Nightingale’s (2000) paper is the editors’ introductory essay to The
Political Economy of Science, Technology, and Innovation in the Elgar series International Library of Critical
Writings in Economics.
47. All reported data are from National Science Board 2004b, tables 4-4 to 4-7.
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$78 billion (or about 28 percent), with about $24 billion allocated to federal government R&D, $17 billion to industry, and $27 billion to universities and colleges.
Between 1953 and 2002, federal R&D expenditures (in 1996 dollars) increased from
$5.3 billion to $70 billion, an average annual increase of 7.8 percent.48 We believe
such evidence supports our claim that government is indeed a Big Player in science
whose funding decisions in terms of absolute magnitudes and the direction of R&D
carry important implications for both the economy and science.
If the outlines of our analysis are accurate, then the problem has no political solution; further politicization of science, as Greenberg (2001) advocates, is like trying to put
out a fire at a gas station with gasoline. The current system makes scientists’ well-being
dependent on the whims of political expediency. It creates winners and losers in the
scientific community, where the winning is not necessarily based on scientific achievement, but on the ability to secure and maintain a flow of politically motivated funding.
The only solution is for the political connections to be bypassed. Such circumvention
is unlikely to happen as a result of initiatives from within science because the scientists
most favored with government funding (those held up as the pillars of the scientific
community) will naturally not want to forgo their political arrangements. A significant
hope for such bypassing is that the trend in industrial support of science, in the form of
the employment and funding of scientists in laboratories that are integral parts of profitmaking firms, will continue to increase. Those in business have realized that scientific
freedom and monetary profit are not necessarily incompatible in that scientists free to
pursue their research into whatever interests them and free to publish the results of such
research openly in normal academic outlets can still, through their expertise and specialized knowledge of the current publications in their field, contribute to in-house projects
geared to creating revenue-generating products. Moreover, in certain areas, particularly
in the biological sciences, access to findings prior to formal publication gives the firm a
jump on the competition that can be profitable in itself.49
Such a provisional prognosis is sure to be controversial. We are only too aware
that the topic of government funding of science is a large and complex one and,
to make things more difficult, one more likely to be discussed in normative rather
than positive terms. Our objective in this article and in future work is to provide a
positive analysis of the effects of government funding on science and to illustrate the
predicted effects empirically. Our basic approach, made evident in the current article,
is informed by a model of science as an adaptive knowledge-generating order whose
48. Over the same period, nongovernment (industry, universities and colleges, and nonprofit organizations) funding of R&D increased on average by 26.6 percent per year, with the great majority of the
absolute increase accounted for by R&D originating in industry and most of that increase (approximately
80 percent) since 1982. The evidence also supports the observation that government funding of “basic
research,” as defined in National Science Board 2004a, 4.8, has crowded out industry and especially university funding of research. See table 4-8 in National Science Board 2004b. Also, in this article, we have
not taken account of state-level government funding of science.
49. The history of the Human Genome Project, described in Shreeve 2004, is particularly instructive in
this respect.
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fundamental transactions involve publication, citation, and criticism. In the context
of this basic social arrangement, we examine the effects of different regimes of funding. We insist at the outset that assessing such matters in terms of the theory relevant
for a market process is not tenable: the market economy is characterized by a pricing
process in a system of profit and loss based on enforceable property exchanges, but
such features are absent from the knowledge-generating process of science. Science
must be analyzed in terms of the incentives and transactions characteristic of science,
not those characteristic of markets.
That government funding, with its presumably scientifically well-intentioned
aims and its politically driven orientation, has significant implications for the kinds
of questions scientists ask and for the kinds of knowledge they generate seems completely plausible. But provided that the standard critical institutions are in play,
a scientific discovery has the same epistemological status whether it has been funded
by the NSF or by a private patron. The problem, then, is that on the surface the specific characteristics of government-funded science and the knowledge it generates are
not evidently any different from those that have originated through private funding.50
We have suggested, however, that the effects are more subtle and that they affect the
structure and function of the scientific arrangements themselves: government funding
affects science in a way analogous to the ways price controls, subsidies, credit expansion, and central planning affect markets, and we have begun in this article to document an institutional structure in science that is made more unstable and maladapted
to its environment as a consequence.
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Acknowledgments: Earlier drafts of this paper were presented at the Society for the Development of
Austrian Economics 2004 Conference, the New York University Colloquium on Market Institutions and
Economics Processes on February 14, 2005, and at the Association for Private Enterprise Education 2005
Conference. We thank Mario Rizzo, Sandy Ikeda, David Harper, Joe Salerno, Chidem Kurdas, Young Back
Choi, Roger Koppl, Heath Spong, Glen Whitman, Roger Garrison, and three referees for comments and
suggestions.
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