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Science & Education

, Volume 28, Issue 9–10, pp 1001–1025 | Cite as

Do Biologists’ Conceptions of Science as a Social Epistemology Align with Critical Contextual Empiricism?

  • Linda FuselierEmail author
  • Justin McFaddenEmail author
  • Katherine Ray KingEmail author
Article
  • 51 Downloads

Abstract

From literature on understandings of the “nature of science” (NOS), we know that sometimes scientists and others that participate in teaching and mentoring in the sciences lack an informed view of the philosophical underpinnings of their discipline. In this study, we ask whether biologists who are also teachers or mentors for college students agree with the tenets of critical contextual empiricism (CCE), a social epistemology of science that foregrounds the importance of a diversity of voices in knowledge-producing communities. We used a Q-sort methodology to examine beliefs about social knowledge construction that are related to teaching science inclusively. Overall, we found that biologists-teachers held viewpoints somewhat consistent with the tenets of Critical Contextual Empiricism. Although participants shared many beliefs in common, we found two significantly different groups of participants that were characterized under the themes “knowledge is constructed by people” and “the truth is out there.” Overall, although participants believed a diversity of cognitive resources aids scientific communities, they failed to recognize the more nuanced ways certain social interactions might impact objective knowledge production. For one group, outside of a belief that collaboration in science is valuable, other social influences on science were assumed to be negative. For a second group, the search for universal truth and the separation of rational and social aspects was critical for scientific objectivity. We use the results of our Q-sort to identify areas for professional development focused on inclusive science teaching and to recommend the explicit teaching of CCE to science educators.

Keywords

Epistemological beliefs Nature of science Q methodology 

Notes

Funding Information

Spencer Small Grant: #201700080

Compliance with Ethical Standards

Conflict of Interest

The authors declare that they have no conflict of interest.

References

  1. Abd-El-Khalick, F. (2012). Examining the sources for our understandings about science: Enduring conflations and critical issues in research on nature of science in science education. International Journal of Science Education, 34(3), 353–374.Google Scholar
  2. Abd-El-Khalick, F., Waters, M., & Le, A. (2008). Representations of nature of science in high school chemistry textbooks over the past four decades. Journal of Research in Science Teaching., 45(7), 835–855.Google Scholar
  3. Allchin, D. (1999). Values in science: An educational perspective. Science & Education, 8(1), 1–12.Google Scholar
  4. Allchin, D. (2012). Teaching the nature of science through scientific errors. Science Education, 96(5), 904–926.Google Scholar
  5. Allchin, D. (2014). From science studies to scientific literacy: A view from the classroom. Science & Education., 23, 1911–1932.Google Scholar
  6. Andrews, T. (2012). What is social constructionism. Grounded Theory Review, 11(1), 39–46.Google Scholar
  7. Barnes, C., Angle, J., & Montgomery, D. (2015). Teachers describe epistemologies of science instruction through Q methodology. School Science and Mathematics, 115(3), 141–150.Google Scholar
  8. Bell, R. L., Mulvey, B. K., & Maeng, J. L. (2016). Outcomes of nature of science instruction along a context continuum: preservice secondary science teachers’ conceptions and instructional intentions. International Journal of Science Education, 38(3), 493–520.Google Scholar
  9. Brewer, C. A., & Smith, D. (2011). Vision and change in undergraduate biology education: a call to action. Washington DC: American Association for the Advancement of Science.Google Scholar
  10. Brown, S. R. (1980). Political subjectivity: Applications of Q methodology in political science. New Heaven: Yale University Press.Google Scholar
  11. Cavallo, A. M. L., Rozman, M., Blickenstaff, J., & Walker, N. (2003). Learning, reasoning, motivation, and epistemological beliefs. Journal of College Science Teaching, 33, 18–23.Google Scholar
  12. Cobern, W. W. (2000). The nature of science and the role of knowledge and belief. Science & Education, 9(3), 219–246.Google Scholar
  13. Couló, A. C. (2014). Philosophical dimensions of social and ethical issues in school science education: Values in science and in science classrooms. In International handbook of research in history, philosophy and science teaching (pp. 1087–1117). Dordrecht: Springer.Google Scholar
  14. Deng, F., Chen, D.-T., Tsai, C.-C., & Chai, C. S. (2011). Students’ views of the nature of science: A critical review of research. Science Education, 95, 961–999.Google Scholar
  15. Donnelly, L. A., & Argyle, S. (2011). Teachers’ willingness to adopt nature of science activities following a physical science professional development. Journal of Science Teacher Education, 22, 475–490.Google Scholar
  16. Donner, J. C. (2001). Using Q-sorts in participatory processes: An introduction to the methodology. Social Development Papers, 36, 24–49.Google Scholar
  17. Duschl, R. A. (1988). Abandoning the scientistic legacy in science education. Science Education.Google Scholar
  18. Duschl, R. A., & Grandy, R. E. (2008). Reconsidering the character and role of inquiry in school science: Framing the debates. In Teaching scientific inquiry (pp. 1–37). Netherlands: Brill Sense.Google Scholar
  19. Duschl, R. A., & Osborne, J. (2002). Supporting and promoting argumentation discourse in science education. Studies in Science Education., 38(1), 39–72.Google Scholar
  20. Dziopa, F., & Ahern, K. (2011). A systematic literature review of the applications of Q-technique and its methodology. Methodology.,7(2), 39–55.Google Scholar
  21. Engle, R. A. (2006). Framing interactions to foster generative learning: A situative explanation of transfer in a community of learners classroom. The Journal of the Learning Sciences, 15(4), 451–498.Google Scholar
  22. Erduran, S., & Dagher, Z. R. (2014). Reconceptualizing the nature of science for science education: Scientific knowledge, practices and other family categories (Vol. 43). Springer.Google Scholar
  23. Fuselier, L., & Jackson, K. J. (2010). Perceptions of collaboration, equity and values in science among female and male college students. Journal of Baltic Science Education, 9, 109–118.Google Scholar
  24. Giere, R. (1988). Explaining science: A cognitive approach. Bloomington: Indiana University Press.Google Scholar
  25. Godlee, F., Smith, J., & Marcovitch, H. (2011). Wakefield’s article linking MMR vaccine and autism was fraudulent. BMJ 342 (jan05 1):c7452–c7452.Google Scholar
  26. Gould, S. J. (1981). The Mismeasure of Man (p. 444). Norton & Co..Google Scholar
  27. Griffard, P. B., Mosleh, T., & Kubba, S. (2013). Developing the inner scientist: book club participation and the nature of science. CBE-Life Sciences Education, 12, 80–91.Google Scholar
  28. Gross, P. R., & Levitt, N. (1993). Higher superstition: The academic left and its quarrels with science. Baltimore: The Johns Hopkins University Press.Google Scholar
  29. Haraway, D. (1988). Situated knowledges: the science question in feminism and the privilege of partial perspective. Feminist Studies, 14, 575–599.Google Scholar
  30. Harding, S. (1986). The Science Question in Feminism. New York: Cornell University Press.Google Scholar
  31. Harding, S. (1991). Whose science? Whose knowledge? Thinking from Women’s Lives. New York: Cornell University Press.Google Scholar
  32. Hasweh, M. Z. (1996). Effects of science teachers’ epistemological beliefs in teaching. Journal of Research in Science Teaching, 33, 47–63.Google Scholar
  33. Hurtado, S., Cabrera, N. L., Lin, M. H., Arellano, L., & Espinosa, L. L. (2008). Diversifying science: Underrepresented student experiences in structured research programs. Research in Higher Education, 50(2), 189–214.Google Scholar
  34. Hutson, G., & Montgomery, D. (2011). Demonstrating the value of extending qualitative research strategies into Q. Operant Subjectivity, 34(4), 234–246.Google Scholar
  35. Irzik, G., & Nola, R. (2011). A family resemblance approach to the nature of science for science education. Science & Education, 20(7-8), 591–607.Google Scholar
  36. Irzik, G., & Nola, R. (2014). New directions for nature of science research. In International handbook of research in history, philosophy and science teaching (pp. 999–1021). Dordrecht: Springer.Google Scholar
  37. Kampourakis, K. (2016). The “general aspects” conceptualization as a pragmatic and effective means to introducing students to nature of science. Journal of Research in Science Teaching, 53(5), 667–682.Google Scholar
  38. Kampourakis, K. (2017). Science teaching in university science departments. Science & Education, 26(3-4), 201–203.Google Scholar
  39. Kelly, G. J. (2008). Inquiry, activity, and epistemic practice. In Teaching Scientific Inquiry: Recommendations for Research and Implementation (pp. 99–91). Netherlands: Brill Sense.Google Scholar
  40. Kelly, G. (2014). Inquiry teaching and learning: Philosophical considerations. In International handbook of research in history, philosophy and science teaching (pp. 1363–1380). New York: Springer.Google Scholar
  41. King, M. M., Bergstrom, C. T., Correll, S. J., Jacquet, J., & West, J. D. (2017). Men Set Their Own Cites High: Gender and Self-citation across Fields and over Time. Socius.  https://doi.org/10.1177/2378023117738903.Google Scholar
  42. Knorr-Cetina, K. (1999). Epistemic cultures: How the sciences make knowledge. Cambridge: Harvard University Press.Google Scholar
  43. Kourany, J. A. (2010). Philosophy of science after feminism. New York: Oxford University Press.Google Scholar
  44. Kutrovátz, G., & Zemplén, G. A. (2014). Social studies of science and science teaching. In International Handbook of Research in History, Philosophy and Science Teaching (pp. 1119–1141). Netherlands: Springer.Google Scholar
  45. Lariviere, V., & Ni, C. (2013). Bibliometrics: Global gender disparities in science: Nature news & comment. Nature. http://www.nature.com/news/bibliometrics-global-gender-disparities-in-science-1.14321.
  46. Lederman, N. G. (2007). Nature of science: Past, present, and future. In Handbook of research on science education (pp. 831–880). Mahwah: Lawrence Erlbaum Associates.Google Scholar
  47. Lederman, N. G., & Lederman, J. S. (2004). Revising instruction to teach nature of science: modifying activities to enhance student understanding of science. The Science Teacher, 71(9), 36–39.Google Scholar
  48. Lederman, N. G., Abd-El-Khalick, F., Bell, R. L., & Schwartz, R. S. (2002). Views of nature of science questionnaire: Toward valid and meaningful assessment of learners’ conceptions of nature of science. Journal of Research in Science Teaching., 39, 497–521.Google Scholar
  49. Lederman, N. G., Lederman, J. S., & Antink, A. (2013). Nature of science and scientific inquiry as contexts for the learning of science and achievement of scientific literacy. International Journal of Education in Mathematics, Science and Technology., 1, 138–147.Google Scholar
  50. Lee, E. A., & Brown, J. J. (2018). Connecting inquiry and values in science education: An approach based on John Dewey’s philosophy. Science & Education, 27, 63–79.Google Scholar
  51. Liu, S. Y., & Tsai, C. C. (2008). Differences in the scientific epistemological views of undergraduate students. International Journal of Science Education, 30, 1055–1073.Google Scholar
  52. Longino, H. (1990). Science as Social Knowledge. New Jersey: Princeton University Press.Google Scholar
  53. Longino, H. (2002). The fate of knowledge. Princeton: Princeton University Press.Google Scholar
  54. Maliniak, D., Powers, R., & Walter, B. F. (2013). The gender citation gap in international relations. International Organization, 67(4), 889–922.Google Scholar
  55. Matthews, M. (2014). International handbook of research in history, philosophy and science teaching. New York: Springer.Google Scholar
  56. McComas, W. (2004). Keys to teaching the nature of science. Science Teacher, 71, 24–27.Google Scholar
  57. McKeown, B., & Thomas, D. (1988). Quantitative applications in the social sciences: Q methodology. Thousand Oaks: SAGE Publications.Google Scholar
  58. Medina, J. (2013). The epistemology of resistance: Gender and racial oppression, epistemic injustice, and the social imagination (p. 332). New York: Oxford University Press.Google Scholar
  59. Merton, R. K. (1973). The sociology of science: Theoretical and empirical investigations. University of Chicago Press.Google Scholar
  60. Miller, M. C. D., Monplaisir, L. M., Offerdahl, E. G., Cheng, F. C., & Ketterling, G. L. (2010). Comparison of views of the nature of science between natural science and nonscience majors. CBE Life Sciences Education, 9, 45–54.Google Scholar
  61. Muis, K. R., & Foy, M. J. (2010). The effects of teachers’ beliefs on elementary students’ beliefs, motivation, and achievement in mathematics. In Personal epistemology in the classroom: theory, research and implications for practice (pp. 435–469). Cambridge University Press: New York.Google Scholar
  62. Musil, C. M. (2001). Hermit crabs, women and scientific literacy. In Gender, Science and the Undergraduate Curriculum: Building Two-Way Street. Washington D.C.: Association of American Colleges and Universities.Google Scholar
  63. National Academy of Science (NAS). (2009). On being a scientist: A guide to responsible conduct in research. 3rd ed. Committee on Science, Engineering and Public Policy. Washington, D.C.: National Academies Press.Google Scholar
  64. National Science Board. (2016). Science and Engineering Indicators 2016. Arlington: National Science Foundation (NSB-2016-1).Google Scholar
  65. Neff, M. W. (2011). What research should be done and why? Four competing visions among ecologists. Frontiers in Ecology and the Environment, 9(8), 462–469.Google Scholar
  66. Niaz, M. (2014). Science textbooks: The role of history and philosophy of science. In International handbook of research in history, philosophy and science teaching (pp. 1411–1441). Springer: Dordrecht.Google Scholar
  67. Niaz, M., & Maza, A. (2011). Nature of science in general chemistry textbooks. Dordrecht: Springer.Google Scholar
  68. Norris, S. P., & Phillips, L. M. (2003). How literacy in its fundamental sense is central to scientific literacy. Science Education, 87, 224–240.Google Scholar
  69. Osborne, J., Collins, S., Ratcliffe, M., Millar, R., & Duschl, R. (2003). What “ideas-about-science” should be taught in school science? A Delphi study of the expert community. Journal of Research in Science Teaching, 40(7), 692–720. Google Scholar
  70. Posner, J., Strike, K., Hewson, P., & Gertzog, W. (1982). Accommodation of a scientific conception: Toward a theory of conceptual change. Science Education, 66, 211–227.Google Scholar
  71. Robbins, P., & Krueger, R. (2000). Beyond bias? The promise and limits of Q method in human geography. The Professional Geographer, 52(4), 636–648.Google Scholar
  72. Ryan, A. G., & Aikenhead, G. (1992). Students’ perceptions about the epistemology of science. Science Education, 76(6), 559–580.Google Scholar
  73. Sandler, B. R., & Hall, R. M. (1986). The campus climate revisited: Chilly for women faculty, administrators, and graduate students. Washington D.C: Association of American Colleges Project on the Status and Education of Women.Google Scholar
  74. Schmolck, P. (2014). PQMethod (version 2.35). Retrieved from http://schmolck.userweb.mwn.de/qmethod/.
  75. Solomon, M. (2008). Social epistemology of science. In R. A. Duschl & R. E. Grandy (Eds.), Teaching Scientific Inquiry: Recommendations and Implementation (pp. 86–94). Chicago: Brill Sense.Google Scholar
  76. Sreejith, K. K. (2011). Critical contextual empiricism and its implications for science education. Episteme-4 Proceedings (fourth international conference to review research on Science Technology and Mathematics Education), Homi Bhabha Centre for Science Education, TIFR, Mumbai, Macmillan advanced research series, MacmillanGoogle Scholar
  77. Sundberg, M. D., Armstrong, J., & Eischusen, E. W. (2005). A reappraisal of the status of introductory biology laboratory education in US colleges and universities. American Biology Teacher., 67, 525–529.Google Scholar
  78. Walker, K. A., & Zeidler, D. L. (2007). Promoting discourse about socioscientific issues through scaffolded inquiry. International Journal of Science Education, 29(11), 1387–1410.Google Scholar
  79. Watts, S., & Stenner, P. (2012). Doing Q methodological research: Theory, method and interpretation. Los Angeles: Sage.Google Scholar
  80. Wong, S., & Hodson, D. (2010). More from the horse’s mouth: What scientists say about science as a social practice. International Journal of Science Education, 32(11), 1431–1463.Google Scholar
  81. Wong, S. L., & Hodson, D. (2009). From horse’s mouth: What scientists say about scientific investigation and scientific knowledge. Science Education, 93, 109–130.Google Scholar
  82. Wylie, A., Dupré, J., & Kincaid, H. (2007). Value-free science? Ideals and illusions. Oxford: Oxford University Press.Google Scholar
  83. Zemplen, G. A. (2009). Putting sociology first–Reconsidering the role of the social in nature of science. Science & Education, 18, 525–560.Google Scholar

Copyright information

© Springer Nature B.V. 2019

Authors and Affiliations

  1. 1.Biology DepartmentUniversity of LouisvilleLouisvilleUSA
  2. 2.College of Education and Human DevelopmentUniversity of LouisvilleLouisvilleUSA

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