Mertonian norms
In 1942, Robert K. Merton introduced "four sets of institutional imperatives taken to comprise the ethos of modern science... universalism, communism, disinterestedness, and organized skepticism."[1] The subsequent portion of his book, The Sociology of Science, elaborated on these principles at "the heart of the Mertonian paradigm—the powerful juxtaposition of the normative structure of science with its institutionally distinctive reward system".[2]
Description and motivation
Merton defines this 'ethos' with reference to Albert Bayet's 1931 work « La Morale De La Science », which "abandons description and analysis for homily" as "that affectively toned complex of values and norms which is held to be binding on the man of science". He attempted to clarify it, given that previously it had not been 'codified'; Merton uses Bayet's remark that 'this scientific ethos [morale] does not have its theoreticians, but it has its artisans. It does not express its ideals, but serves them: it is implicated in the very existence of science'.
The norms are expressed in the form of prescriptions, proscriptions, preferences, and permissions. They are legitimatized in terms of institutional values. These imperatives , transmitted by precept and example and reenforced by sanctions are in varying degrees internalized by the scientist, thus fashioning his scientific conscience or, if one prefers the latter-day phrase, his super-ego... [This scientific ethos] can be inferred from the moral consensus of scientists as expressed in use and wont, in countless writings on the scientific spirit and in moral indignation directed toward contraventions of the ethos.
An examination of the ethos of modern science is only a limited introduction to a larger problem: the comparative study of the institutional structure of science. Although detailed monographs assembling the needed comparative materials are few and scattered, they provide some basis for the provisional assumption that “science is afforded opportunity for development in a democratic order which is integrated with the ethos of science.” This is not to say that the pursuit of science is confined to democracies.
His attempt at 'codification' sought to determine which social structure[s] "provide an institutional context for the fullest measure of [scientific] development", i.e. lead to scientific achievement rather than only "potentialities". He saw these "institutional imperatives (mores)" as being derived from the [institutional] "goal of science" ("the extension of certified knowledge") and "technical methods employed [to] provide the relevant definition of knowledge: empirically confirmed and logically consistent statements of regularities (which are, in effect, predictions)".
The entire structure of technical and moral norms implements the final objective. The technical norm of empirical evidence, adequate and reliable, is a prerequisite for sustained true prediction; the technical norm of logical consistency, a prerequisite for systematic and valid prediction. The mores of science possess a methodologic rationale but they are binding, not only because they are procedurally efficient, but because they are believed right and good. They are moral as well as technical prescriptions.
Four Mertonian norms
The four Mertonian norms can be summarised as:
- universalism: scientific validity is independent of the sociopolitical status/personal attributes of its participants; to honour this principle, the scientific project requires organisations to provide equality of opportunity[3]
- “communism”: all scientists should have common ownership of scientific goods (intellectual property), to promote collective collaboration; secrecy is the opposite of this norm.[4]
- disinterestedness: scientific institutions act for the benefit of a common scientific enterprise, rather than for the personal gain of individuals within them
- organized scepticism: scientific claims should be exposed to critical scrutiny before being accepted: both in methodology and institutional codes of conduct.[5]
Universalism
The two aspects of Merton's universalism are expressed in the statements that "objectivity precludes particularism" and "free access to scientific pursuits is a functional imperative".
Firstly, that all scientists' claims ("truth-claims") should be subjected to the same 'pre-established impersonal criteria' regardless of their source ("personal or social attributes of their protagonist"), i.e. regardless of race, nationality, culture, or gender. He saw universalism as "rooted deep in the impersonal character of science", and yet also saw the institution of science itself as part of a larger social structure which, paradoxically, was "not always integrated" into societal structure and could generate friction (to the detriment of the scientific project):
Particularly in times of international conflict, when the dominant definition of the situation is such as to emphasize national loyalties, the man of science is subjected to conflicting imperatives of scientific universalism and ethnocentric particularism.
Secondly, that restricting scientific careers on anything but lack of competence was to "prejudice the furtherance of knowledge". Merton again noted how the ethos of science may be inconsistent with a society's, and "however inadequately it may be put into practice, the ethos of democracy includes universalism as a dominant guiding principle". He described this inadequacy of laissez-faire democratic processes as leading ultimately to false differential accumulation and as such, to increasing regulation of science under political authority which must be counteracted through "new technical forms of organization" towards equality of opportunity.
“Communism”
Common ownership of scientific goods is integral to science: "a scientists' claim to “his” intellectual “property” is limited to that of recognition and esteem".
The substantive findings of science are a product of social collaboration and are assigned to the community. They are a common heritage in which the equity of the individual producer is severely limited... rather than exclusive ownership of the discoverer and their heirs.
Communism is used sometimes in quotation marks, yet elsewhere scientific products are described without them as communized. Merton states the "communism of the scientific ethos" is flatly incompatible with "the definition of technology as “private property” in a capitalistic economy", noting the claimed right of an inventor to withhold information from the public in the case of the U.S. v. American Bell Telephone Co.
A corollary to the need for common ownership of scientific knowledge is the imperative for "full and open" communication (which he saw in J. D. Bernal's writings Bernal, J. D. (1939). The social function of science.), as opposed to secrecy (which he saw espoused in the work of Henry Cavendish, "selfish and anti-social").
Disinterestedness
Distinct from altruism, scientists should act for the benefit of a common scientific enterprise, rather than for personal gain.[6] He wrote that this motivation was borne out of institutional control (including fear of institutional sanctions), and from psychological conflict (due to internalisation of the norm).
Merton observed a low rate of fraud in science ("virtual absence... which appears exceptional"), which he believed stemmed from the intrinsic need for 'verifiability' and expert scrutiny by peers ("rigorous policing, to a degree perhaps unparalleled in any other field of activity"), as well as its 'public and testable character'.
Self-interest (in the form of self-aggrandisement and/or exploitation of "the credulity, ignorance, and dependence of the layman") is the logical opposite of disinterestedness, and may be appropriated by authority "for interested purposes" (Merton notes "totalitarian spokesmen on race or economy or history" as examples, and describes science as enabling such "new mysticisms" that "borrow prestige").
Organized skepticism
Skepticism (i.e. "temporary suspension of judgement", and 'detached' critical scrutiny) is central to both scientific methodology and institutions.
The scientific investigator does not preserve the cleavage between the sacred and the profane, between that which requires uncritical respect and that which can be objectively analyzed.
Merton suggested in closing the chapter that this characteristic of science, and the "diffuse, frequently vague apprehension [of threat] to the current distribution of power" that skepticism presents, rather than from any specific conflicts "which appear to invalidate particular dogmas of church, economy, or state".
Conflict becomes accentuated whenever science extends its research to new areas toward which there are institutionalized attitudes or whenever other institutions extend their control over science. In modern totalitarian society, anti-rationalism and the centralization of institutional control both serve to limit the scope provided for scientific activity.
Later variants
Later work has added "originality", and shortened 'organized scepticism' to 'scepticism', producing the acronym 'CUDOS' (sometimes these 5 concepts are misleadingly named 'Mertonian norms').[7] Other works additionally replace 'communism' with 'communalism' (e.g. Ziman 2000).[8]
See also
Notes
- ↑ Merton 1973
- ↑ Merton 1973, p. 281
- ↑ Merton 1973, p. 270
- ↑ Merton 1973, pp. 273–5
- ↑ Merton 1973, pp. 277–8
- ↑ Merton 1973, pp. 275–277
- ↑ Bruce Macfarlane & Ming Cheng (2008). "Communism, Universalism and Disinterestedness: Re-examining Contemporary Support among Academics for Merton's Scientific Norms" (PDF). J Acad Ethics. Springer (6): 67–78. doi:10.1007/s10805-008-9055-y.
- ↑ Ziman 2000
References
- Merton, Robert K. (1973) [1942], "The Normative Structure of Science", in Merton, Robert K., The Sociology of Science: Theoretical and Empirical Investigations, Chicago: University of Chicago Press, ISBN 978-0-226-52091-9, OCLC 755754
- Mitroff, Ian I. (1974), "Norms and Counter-Norms in a Select Group of the Apollo Moon Scientists: A Case Study of the Ambivalence of Scientists", American Sociological Review, 39 (4): 579–595, doi:10.2307/2094423, JSTOR 2094423
- Ziman, John (2000), Real Science: what it is, and what it means, Cambridge: Cambridge University Press, ISBN 978-0-521-77229-7, OCLC 41834678
- Godfrey-Smith, Peter (2003), Theory and Reality, Chicago: University of Chicago Press, ISBN 978-0-226-30062-7