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Employment and Training Services > Training and Education > Science, Technology, Engineering, and Math (STEM) programs
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Employment and Training Services > Training and Education > Science, Technology, Engineering, and Math (STEM) programs
Khan, S. (2005). Teaching strategies designed to change the undergraduate experience for college women learning chemistry. Journal of Women and Minorities in Science and Engineering 11, 365-387.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Causal Impact Analysis
- Education and skills gains-Low-No impactsEducation and skills gains
Topic Area: Registered Apprenticeship and Work-Based Learning
Topic Area: Community College
Study Type: Causal Impact Analysis
- Earnings and wages-Mod/high-Favorable impactsEarnings and wages
- Employment-Mod/high-Favorable impactsEmployment
- Public benefits receipt-Mod/high-No impactsPublic benefit receipt
Bakian, A.V., & Sullivan, K.A. (2010). The Effectiveness of Institutional Intervention on Minimizing Demographic Inertia and Improving the Representation of Women Faculty in Higher Education. International Journal of Gender, Science and Technology, 2(2), 207-234.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Causal Impact Analysis
- Employment-Low-Favorable impactsEmployment
Phelps, M. (2012). The effects of hands-on activities on middle school females’ spatial skills and interest in engineering and technology-based careers. Proceedings of the 2012 American Society for Engineering Education Annual Conference & Exposition. Washington, DC: American Society for Engineering Education.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Causal Impact Analysis
- Attitudes-Low-Favorable impactsAttitudes
Peterfreund, A., Rath, K., Xenos, S., & Bayliss, F. (2007). The impact of supplemental instruction on students in STEM courses: Results from San Francisco State University. Journal of College Student Retention: Research, Theory & Practice, 9(4), 487-503.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Causal Impact Analysis
- Education and skills gains-Low-No impactsEducation and skills gains
Bhanot, R.T., & Jovanovic, J. (2009). The links between parent behaviors and boys’ and girls’ science achievement beliefs. Applied Developmental Science, 13(1), 42-59.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Descriptive Analysis
Riegle-Crumb, C., King, B., Grodsky, E., & Muller, C. (2012). The more things change, the more they stay the same? Prior achievement fails to explain gender inequality in entry into STEM college majors over time. American Educational Research Journal, 49(6), 1048-1073.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Descriptive Analysis
Szelényi, K., & Inkelas, K. (2011). The role of living–learning programs in women’s plans to attend graduate school in STEM fields. Research in Higher Education, 52(4), 349-369.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Causal Impact Analysis
- Attitudes-Low-Favorable impactsAttitudes
Gunderson, E., Ramirez, G., Levine, S., & Beilock, S. (2012). The role of parents and teachers in the development of gender-related math attitudes. Sex Roles, 66, 153-166.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Descriptive Analysis
Starobin, S., & Bivens, G. (2014). The role of secondary school and community college collaborations to increase Latinas in engineering in a rural community. New Directions for Community Colleges, 2014(165), 17-23.
Topic Area: Women in Science, Technology, Engineering, & Math (STEM)
Study Type: Descriptive Analysis