Investigating the quantity–quality relationship in scientific creativity: an empirical examination of expected residual variance and the tilted funnel hypothesis

Among scientists who study scientific production, the relationship between the quantity of a scientist’s production and the quality of their work has long been a topic of empirical research and theoretical debate. One principal theoretical perspective on the quantity–quality relationship has been the equal odds baseline, which posits that a scientist’s number of high-quality products increases linearly with their total number of products, and that there is a zero correlation between a scientist’s total number of products and the average quality of those products. While these central tenets of the equal odds baseline are well known, it also posits a number of more specific and less discussed aspects of the quality–quantity relation, including the expected residual variance and heteroscedastic errors when quality is regressed on quantity. After a careful examination of the expected variance by means of a non-parametric bootstrap approach, we forward a further prediction based on the heteroscedasticity implied by the equal-odds baseline that we term the tilted funnel hypothesis, that describes the shape of a bivariate scatterplot when quality is regressed on quantity, as well as the change in the strength of slope coefficients at different conditional quantiles of the quality distribution. In this study, we empirically test the expected residual variance and the tilted funnel hypothesis across three large datasets (including approximately 1.5 million inventors, 1800 psychologists, and 20,000 multidisciplinary scientists). Across all of the data sets, the results empirically supported the tilted funnel hypothesis, and therefore the results provided further evidence of the utility of the equal odds baseline.

[1]  Keming Yu,et al.  Quantile regression: applications and current research areas , 2003 .

[2]  Boris Forthmann,et al.  Testing equal odds in creativity research. , 2019 .

[3]  Matthijs Baas,et al.  The dual pathway to creativity model: Creative ideation as a function of flexibility and persistence , 2010 .

[4]  Debashis Kushary,et al.  Bootstrap Methods and Their Application , 2000, Technometrics.

[5]  Boris Forthmann,et al.  On the Conceptual Overlap between the Fluency Contamination Effect in Divergent Thinking Scores and the Chance View on Scientific Creativity , 2020 .

[6]  S. West,et al.  Model fit and model selection in structural equation modeling. , 2012 .

[7]  R. Koenker Quantile Regression: Name Index , 2005 .

[8]  Rok Blagus,et al.  Comparison of bibliometric measures for assessing relative importance of researchers , 2015, Scientometrics.

[9]  L. Cronbach The Reliability of Ratio Scores , 1941 .

[10]  Jian Wang,et al.  Measuring originality in science , 2019, Scientometrics.

[11]  H. Holling,et al.  Understanding the confounding effect of fluency in divergent thinking scores: Revisiting average scores to quantify artifactual correlation. , 2020 .

[12]  Yves Rosseel,et al.  lavaan: An R Package for Structural Equation Modeling , 2012 .

[13]  Michael C. Calver,et al.  Should we use the mean citations per paper to summarise a journal’s impact or to rank journals in the same field? , 2009, Scientometrics.

[14]  Naomi S. Altman,et al.  Quantile regression , 2019, Nature Methods.

[15]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[16]  Alexander von Eye,et al.  How does scientific success relate to individual and organizational characteristics? A scientometric study of psychology researchers in the German-speaking countries , 2012, Scientometrics.

[17]  Nicole J. Saam,et al.  Lotka's law reconsidered: The evolution of publication and citation distributions in scientific fields , 1999, Scientometrics.

[18]  J. P. Guilford,et al.  Intelligence, creativity, and their educational implications , 1968 .

[19]  Jacob Cohen Statistical Power Analysis for the Behavioral Sciences , 1969, The SAGE Encyclopedia of Research Design.

[20]  Vikram Nanda,et al.  Truncation Bias Corrections in Patent Data: Implications for Recent Research on Innovation , 2017 .

[21]  Creativity in neurosurgical publications. , 1987, Neurosurgery.

[22]  Sebastian E. Wenz What Quantile Regression Does and Doesn't Do: A Commentary on Petscher and Logan (2014). , 2018, Child development.

[23]  D. Simonton Genius and g: Intelligence and Exceptional Achievement , 2003 .

[24]  Ayako Kondo,et al.  Researchers’ career transitions over the life cycle , 2016, Scientometrics.

[25]  R. Koenker,et al.  Regression Quantiles , 2007 .

[26]  Denis Dumas,et al.  Relational reasoning and divergent thinking: An examination of the threshold hypothesis with quantile regression , 2018 .

[27]  D. Simonton Creative thought as blind-variation and selective-retention: combinatorial models of exceptional creativity. , 2010, Physics of life reviews.

[28]  C. Ferguson An effect size primer: A guide for clinicians and researchers. , 2009 .

[29]  D. Simonton Scientific Creativity as a Combinatorial Process: The Chance Baseline , 2009 .

[30]  S. M. Lawani,et al.  Some bibliometric correlates of quality in scientific research , 2005, Scientometrics.

[31]  Stefano Allesina,et al.  Supplemental Materials for : And , not Or : Quality , Quantity in Scientific Publishing , 2017 .

[32]  Jian Wang,et al.  Knowledge creation in collaboration networks: Effects of tie configuration , 2016 .

[33]  Yang Wang,et al.  Hot streaks in artistic, cultural, and scientific careers , 2017, Nature.

[34]  Wayne Dennis,et al.  The age decrement in outstanding scientific contributions: Fact or artifact? , 1958 .

[35]  Vetle I. Torvik,et al.  Disambiguation and co-authorship networks of the U.S. patent inventor database (1975–2010) , 2014 .

[36]  Gregory J. Feist Quantity, Quality, and Depth of Research as Influences on Scientific Eminence: Is Quantity Most Important? , 1997 .

[37]  A. Satorra,et al.  Corrections to test statistics and standard errors in covariance structure analysis. , 1994 .

[38]  Dean Keith Simonton,et al.  Scientific Genius: A Psychology of Science , 1988 .

[39]  A. Stirling A general framework for analysing diversity in science, technology and society , 2007, Journal of The Royal Society Interface.

[40]  Houqiang Yu,et al.  Does the average JIF percentile make a difference? , 2016, Scientometrics.

[41]  Frederick L. Oswald,et al.  On the robustness, bias, and stability of statistics from meta-analysis of correlation coefficients : Some initial Monte Carlo findings , 1998 .

[42]  J. Hanspach,et al.  Academia's obsession with quantity. , 2012, Trends in ecology & evolution.

[43]  A. Jensen,et al.  The scientific study of general intelligence : tribute to Arthur R. Jensen , 2003 .

[44]  D. Simonton Creativity in Science: Chance, Logic, Genius, and Zeitgeist , 2004 .

[45]  Geoffrey S. Shideler,et al.  Reviewer interest in a manuscript may predict its future citation potential , 2017, Scientometrics.

[46]  Dean Keith Simonton,et al.  Scientific creativity as constrained stochastic behavior: the integration of product, person, and process perspectives. , 2003, Psychological bulletin.

[47]  Detecting heteroscedasticity in a simple regression model via quantile regression slopes , 2006 .

[48]  J. R. Cole,et al.  Scientific output and recognition: a study in the operation of the reward system in science. , 1967, American sociological review.