Abstract
Spatial training has been indicated as a possible solution for improving Science, Technology, Engineering, and Mathematics (STEM) achievement and degree attainment. Advocates for this approach have noted that the correlation between spatial ability and several measures of STEM achievement suggests that spatial training should focus on improving students’ spatial ability. Although spatial ability can be improved with targeted training, few studies have examined specifically the relation between spatial training and STEM achievement. In this brief report, we review the evidence to date for the effectiveness of spatial training. We argue that spatial training offers one of the many promising avenues for increasing student success in STEM fields, but research studies that show such training causally improve retention, achievement, and degree attainment remain outstanding.
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References
Bao, L., Cai, T., Koenig, K., Fang, K., Han, J., Wang, J., Liu, Q., Ding, L., Cui, L., Luo, Y., Wang, Y., Li, L., & Wu, N. (2009). Learning and scientific reasoning. Science, 323, 586–587.
Bradshaw, C. P., Zmuda, J. H., Kellam, S. G., & Ialongo, N. S. (2009). Longitudinal impact of two universal preventive interventions in first grade on educational outcomes in high school. Journal of Educational Psychology, 101(4), 926–937.
Cheng, Y. L., & Mix, K. S. (2014). Spatial training improves children’s mathematics ability. Journal of Cognition and Development, 15(1), 2–11.
Chittleborough, G., & Treagust, D. F. (2007). The modelling ability of non-major chemistry students and their understanding of the sub-microscopic level. Chemistry Education Research and Practice, 8(3), 274–292.
Dabbs, J. M., Chang, E., Strong, R., & Milun, R. (1998). Spatial ability, navigation strategy, and geographic knowledge among men and women. Evolution and Human Behavior, 19, 89–98.
Daempfle, P. A. (2003). An analysis of the high attrition rates among first year college science, math, and engineering majors. Journal of College Student Retention, 5(1), 37–52.
Devon, R., Engle, R., & Turner, G. (1998). The effects of spatial visualization skill training on gender and retention in engineering. Journal of Women and Minorities in Engineering, 4, 371–380.
Ehrlich, S., Levine, S., & Goldin-Meadow, S. (2006). The importance of gestures in children’s spatial reasoning. Developmental Psychology, 42, 1259–1268.
Hsi, S., Linn, M. C., & Bell, J. E. (1997). The role of spatial reasoning in engineering and the design of spatial instruction. Journal of Engineering Education, 86(2), 151–158.
Jones, S., & Burnett, G. (2008). Spatial ability and learning to program. Human Technology, 4(1), 47–61.
Keehner, M., Tendick, F., Meng, M. V., Anwar, H. P., Hegarty, M., Stoller, M. L., & Duh, Q.-Y. (2004). Spatial ability, experience, and skill in laparoscopic surgery. The American Journal of Surgery, 188, 71–75.
Knapp, A. (2011). Why schools don’t value spatial reasoning. Forbes. Retrieved from http://www.forbes.com/sites/alexknapp/2011/12/27/why-dont-schools-value-spatial-reasoning.
Kozhevnikov, M., Motes, M. A., & Hegarty, M. (2007). Spatial visualization in physics problem solving. Cognitive Science, 31, 549–579.
Lord, T. (1990). Enhancing learning in the life sciences through spatial perception. Innovative Higher Education, 15(1), 5–16.
Lord, T., & Nicely, G. (1997). Does spatial aptitude influence science-math subject preferences of children? Journal of Elementary Science Education, 9(2), 67–81.
Lubinski, D. (2010). Spatial ability and STEM: a sleeping giant for talent identification and development. Personality and Individual Differences, 49, 344–351.
McNeil, N. M., & Alibali, M. W. (2005). Why won’t you change your mind? Knowledge of operational patterns hinders learning and performance on equations. Child Development, 76, 1–17.
Miller, D. I., & Halpern, D. F. (2013). Can spatial training improve long-term outcomes for gifted STEM undergraduates? Learning and Individual Differences, 26, 141–152.
Mix, K. S., & Cheng, Y.-L. (2012). The relation between space and math: developmental and educational implications. Advances in Child Development and Behavior, 42, 197–243.
National Center for Educational Statistics (2012). The nation’s report card: Science 2011 (NCES 2012–465). Washington, D.C.: Institute of Education Sciences, U.S. Department of Education.
National Research Council. (2006). Learning to think spatially. Washington, D.C.: National Academies Press.
National Science Foundation. (2009). Women, minorities, and persons with disabilities in science and engineering. Arlington: National Science Foundation.
Ozdemir, G. (2010). Exploring visuospatial thinking in learning about mineralogy: spatial orientation ability and spatial visualization ability. International Journal of Science and Mathematics Education, 8(4), 737–759.
Park, G., Lubinski, D. L., & Benbow, C. P. (2010). Recognizing spatial intelligence. Scientific American. Retrieved from http://www.scientificamerican.com/article/recognizing-spatial-intel/. Accessed 19 Nov 2014.
Pribyl, J. R., & Bodner, G. M. (1987). Spatial ability and its role in organic chemistry: a study of four organic courses. Journal of Research in Science Teaching, 24(3), 229–240.
Raver, C. C., Jones, S. M., Li-Grining, C. P., Metzger, M., Champion, K. M., & Sardin, L. (2008). Improving preschool classroom processes: preliminary findings from a randomized trial implemented in Head Start settings. Early Childhood Research Quarterly, 23(1), 10–26.
Rudmann, D. (2002). Solving astronomy problems can be limited by intuited knowledge, spatial ability, or both. Paper presented at the Annual Meeting of the American Educational Research Association. New Orleans, LA.
Small, M. Y., & Morton, M. E. (1983). Spatial visualization training improves performance in organic chemistry. Journal of College Science Teaching, 13(1), 41–43.
Smith, M. K., & Knight, J. K. (2012). Using the genetics concept assessment to document presistent conceptual difficulties in undergraduate genetics courses. Genetics, 191(1), 21–32.
Sorby, S. A. (2001). A course in spatial visualization and its impact on the retention of female engineering students. Journal of Women and Minorities in Science and Engineering, 7(2), 153–172.
Sorby, S. A. (2009). Education research in developing 3-D spatial skills for engineering students. International Journal of Science Education, 31(3), 459–480.
Sorby, S. A. (2011). Developing spatial thinking. Independence: Cengage.
Sorby, S. A., Casey, B., Veurink, N., & Dulaney, A. (2013). The role of spatial training in improving spatial and calculus performance in engineering students. Learning and Individual Differences, 26, 20–29.
Stieff, M. (2011). When is a molecule three-dimensional? A task-specific role for imagistic reasoning in advanced chemistry. Science Education, 95(2), 310–336.
Uttal, D. H., & Cohen, C. A. (2012). Spatial thinking and STEM education: when, why and how. Psychology of Learning and Motivation, 57, 147–181.
Uttal, D. H., Meadow, N. G., Tipton, E., Hand, L. L., Alden, A., Warren, C., & Newcombe, N. (2013a). The malleability of spatial skills: a meta-analysis of training studies. Psychological Bulletin, 139(2), 352–402.
Uttal, D. H., Miller, D. I., & Newcombe, N. S. (2013b). Exploring and enhancing spatial thinking links to achievement in science, technology, engineering, and mathematics? Current Directions in Psychological Science, 22(5), 367–373.
Wai, J., Lubinski, D., & Benbow, C. P. (2009). Spatial ability for STEM domains: aligning over fifty years of cumulative psychological knowledge solidifies its importance. Journal of Educational Psychology, 101, 817–835.
Wai, J., Lubinski, D., Benbow, C. P., & Steiger, J. H. (2010). Accomplishment in science, technology, engineering, and mathematics (STEM) and its relation to STEM educational dose: a 25-year longitudinal study. Journal of Educational Psychology, 102, 860–871.
White, J. L., Altschuld, J. W., & Lee, Y. (2006). Persistence of interest in science, technology, engineering, and mathematics: a minority retention study. Journal of Women and Minorities in Science and Engineering, 12(1), 47–64.
Wright, R., Thompson, W. L., Ganis, G., Newcombe, N. S., & Kosslyn, S. M. (2008). Training generalized spatial skills. Psychonomic Bulletin and Review, 15(4), 763–771.
Acknowledgments
We gratefully acknowledge the input of Tim Shipley, Nora Newcombe, and Kristin Gagnier on our ideas for this report.
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Stieff, M., Uttal, D. How Much Can Spatial Training Improve STEM Achievement?. Educ Psychol Rev 27, 607–615 (2015). https://doi.org/10.1007/s10648-015-9304-8
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DOI: https://doi.org/10.1007/s10648-015-9304-8
Keywords
- Spatial ability
- STEM education