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Blue-sky research rarely casts the most light

<ÁñÁ«ÊÓƵ class="standfirst">Myths notwithstanding, devolving research agendas to disciplines has a poor record of success, says Steve Fuller
April 28, 2020
Canadian and British observers illumined by both the sun and an atomic blast of ABLE, a 1-kiloton atomic bomb. January 27, 1951
Source: Alamy

The recent resignation of Mauro Ferrari as president of the European Research Council has thrown into sharp relief the distinction between ¡°basic¡± and ¡°applied¡± research, as understood today.

In the UK, this is particularly topical given that it coincides with the start of parliamentary scrutiny over the role that the government¡¯s proposed ¡°high risk, high reward¡± research agency might play in the nation¡¯s research ecology. But given the squeeze on global public finances across the world that will inevitably extend into the foreseeable future following the Covid-19 pandemic, the time is ripe for a radical, multinational rethink of why taxpayers should be funding research at all.?

According to the prevailing science policy mythology, basic research provides the securest route to generating applications of large-scale, long-term public benefit. The myth has been facilitated by a rather flexible conception of ¡°research impact¡± that has made great play of ¡°unforeseen benefits¡± over an indefinite period of time. The exact grounding of this myth has varied internationally, but the one with greatest totemic status involved the establishment of the US National Science Foundation (NSF) after the Second World War.

This was inspired by Massachusetts Institute of Technology vice-president Vannevar Bush¡¯s The Endless Frontier, which explained the building of the war-ending atomic bomb in terms of the critical mass of distinguished physicists that mobilised behind the cause. However, these researchers did not spontaneously self-organise into the Manhattan Project. Rather, responding to rumours of a Nazi atomic bomb project, the US government, in consultation with scientists such as Princeton-based Albert Einstein, set the parameters of the project, including eligibility for participation.

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But the scientists then went about the project in an unprecedentedly free way. It resulted in massive cost overruns, relatively little oversight and high levels of uncertainty. Eventually, a bomb was successfully detonated in a New Mexico desert, but to what extent is this impressive achievement correctly described as a triumph of ¡°basic research left to its own devices¡±?

Bush and others backing the version of the NSF that Congress passed in 1950 certainly subscribed to that view. But, more importantly, they presumed that for basic research to be ¡°free¡±, it must be devolved to the peer review processes that normally govern discipline-based academic work. However, the Manhattan Project was neither the product of discipline-based academic work nor the straightforward application of such work. It was a profoundly interdisciplinary project that involved not only physicists but also engineers and medical professionals. It took all concerned way outside their intellectual comfort zones.

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A more appropriate model for thinking about research of this sort ¨C as well as for the proposed new UK research agency ¨C is what Donald Stokes, a pioneer of empirical voter studies, called ¡°Pasteur¡¯s Quadrant¡±. Stokes had developed a 2x2 matrix of relationships between ¡°basic¡± and ¡°applied¡± research in the 1990s as part of a prospectus on the possible directions for post-Cold War US science policy. He recognised that Louis Pasteur¡¯s long-term contributions to science ¨C not least in such pandemic-relevant fields as epidemiology and public health ¨C was a case of ¡°applied¡± concerns serving to steer ¡°basic¡± research, rather than the other way around.

Moreover, Pasteur was hardly unique. In the 20th century, the great private foundations (such as Rockefeller) and corporate R&D units (such as Bell Labs) were the main drivers of the signature breakthroughs in molecular biology, behavioural science and neuroscience, as well as information and communication technology, including artificial intelligence.

Of course, the researchers involved were academically well trained. More importantly, academia was central to the normalisation of these breakthroughs into the curriculum, so that many more than the original funders could benefit. However, when it comes to providing an environment for the actual conduct and evaluation of such cutting-edge research, the record of universities ¨C and especially of established academic disciplines ¨C has been chequered, to say the least.

The complaints of academic innovators about their home turf are legion and largely justified. They go beyond lack of time and funds. Peer review itself routinely confuses assessments of the validity of work judged on its own terms and in terms of some larger discipline-based agenda that, in the end, may matter only to other academics.

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The UK¡¯s new funding agency is, of course, based on the US Defense Advanced Research Projects Agency (Darpa). The right lesson to take from the Manhattan Project would have been to establish Darpa immediately, rather than the NSF. Darpa eventually did get created, of course, but almost a decade later, and in direct response to the Soviet Union¡¯s launch of Sputnik 1 in 1957. By that time, the basic/applied science policy mythology had already set in.

The UK¡¯s Darpa should be seen as a direct challenge to this mythology. In the context of tightened public funding, why should we presume that ¡°basic research¡± of the truly fundamental sort is more likely to come from the disciplinary agendas of self-appointed ¡°basic researchers¡± than from more organised responses to external exigencies agreed by scientists, governments and the public?

Steve Fuller is Auguste Comte professor of social epistemology at the University of Warwick.

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<ÁñÁ«ÊÓƵ class="pane-title"> Reader's comments (4)
I realise this is about some UK research council on which subject I have no opinion. But I think the article rather misses the point about the Manhattan project and DARPA projects. The Manhattan project was not curiosity driven research, but it was made possible because prior to this applied project there was curiosity driven research. Presumably same for DARPA projects. My involvement in a DARPA project was made possible by my own curiosity driven research, not by any directives from a funding agency for applied research.
I agree entirely with ohrstrom's comment. The point is that "basic" (curiousity-driven, blue skies, discovery etc) gives freedom to develop new techniques, approaches, ways of thinking that can then be applied. These skills would not necessarily be available if "basic" research was not funded. The soft steer of the impact agenda nods to this and encourages those doing basic research to consider and engage with the "real world" applications that might result. If everything was only top down "applied" or "strategic" research, then we would be stuck in a loop of regurgitating accepted knowledge. Not only that, the real danger of government interference with what scientists should be researching would stifle innovation and freedom.
I agree with previous two speakers comments. The article seems to adopt linear model thinking with regards the research process which has been outdated for many years. The boundary between basic and applied research is increasingly blurred and not always easily differentiated. However, there are significant dangers associated with cutting public funding for basic research with the expectation that the private will pick up the slack. This includes underinvestment of funds in certain areas, maintaining of status quo, damages to certain disciplines e.g. theoretical mathematics and lack of skills developed to facilitate future thinking.
People who defend the public funding of research on a large scale should really avoid self-serving arguments. ¡®Curiosity¡¯ is a self-certifying term and should have no place in science policy ¨C and truth be told, doesn¡¯t have a technical definition anywhere else. Insofar as ¡®curiosity¡¯ means anything at all, it can be found in all intellectual endeavours, be it prompted by nature, the state, industry or simply one¡¯s own imagination. The term should not be used prejudicially against ¡®applied¡¯ research. Here it is worth recalling Pasteur¡¯s own maxim, ¡®Discovery favours the prepared mind¡¯. The maxim takes curiosity as given. What matters is whether one¡¯s mind is capable to meet the challenge of solving an important problem, again regardless of its origins. Academia has done a fine job of preparing people¡¯s minds to make significant discoveries. However, it doesn¡¯t follow that academia has done an equally good job of providing the context for making ¨C and to some extent, even justifying -- those discoveries. Academia¡¯s mixed track record will undoubtedly come to the fore in the post-pandemic public research funding debate.
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