High-quality Science, Technology, Engineering, and Mathematics (STEM) education provides unique opportunities for students’ futures. STEM education requires integrating multiple disciplines and promotes students’ problem-solving skills when engaging with real-world problems like engineers. Teachers have prominent roles in helping students develop basic concepts, connect their interests to their abilities, and sustain their curiosity from the early years. The present study used a predictive correlational survey design to investigate students’ STEM career interests and the effects of teacher-related variables: teacher attitudes and self-efficacy beliefs. The participants were 421 middle school students and 160 teachers randomly selected from the target population. STEM Attitudes Scale and Teacher Self-Efficacy Scale for STEM Practice were used to collect data from teachers, and STEM Career Interest Scale (STEM-CIS) was used for data collection from students. Normality assumptions were tested, and parametric tests were used. One sample t-test was used to compare students’ observed mean scores to the expected mean scores and multiple linear regression to investigate the predictivity of teacher attitudes and self-efficacy beliefs on student interests. The results revealed positive weak, and moderate relationships between teacher attitudes, self-efficacy beliefs, and student interests. Additionally, teacher efficacy beliefs had stronger predictivity on student interests than attitudes had.

Al Salami, M. K., Makela, C. J., & De Miranda, M. A. (2017). Assessing changes in teachers’ attitudes toward interdisciplinary STEM teaching. International Journal of Technology and Design Education, 27(1), 63-88..

Aydın, G., Saka, M., & Guzey, S. (2017). 4-8. sınıf öğrencilerinin fen, teknoloji, mühendislik, matematik (STEM=FETEMM) tutumlarının incelenmesi. Mersin University Journal of the Faculty of Education, 13(2), 787-802.

Bahar, A., & Adiguzel, T. (2016). Analysis of factors influencing interest in STEM career: Comparison between American and Turkish high school students with high ability. Journal of STEM Education: Innovations and Research, 17(3), 64-69.

Blanchard, M. R., Gutierrez, K. S., Hoyle, K. S., Painter, J. L., & Ragan, N. S. (2018). Rural, underrepresented students’ motivation, achievement, and perceptions in after-school STEM Clubs. In Finlayson, O., McLoughlin, E., Erduran, S., & Childs, P. (Eds.), Electronic Proceedings of the ESERA 2017 Conference. Research, Practice and Collaboration in Science Education Part 2 (co-ed. Tytler, R., & Carvalho, G. S.), (pp. 264–272). Dublin Ireland: Dublin City University.

Brown, P. L., Concannon, J. P., Marx, D., Donaldson, C. W., & Black, A. (2016). An examination of middle school students’ STEM self-efficacy with relation to interest and perceptions of STEM. Journal of STEM Education, 17(3), 27-38.

Brown, R., Brown, J., Reardon, K., &Merrill, C. (2011). Understanding STEM: Current perceptions. Technology and Engineering Teacher, 70(6), 5-9.

Büyüköztürk, Ş., Kılıç Çakmak, E., Akgün, Ö.E., Karadeniz, Ş., & Demirel, F. (2011). Bilimsel araştırma yöntemleri. Ankara: Pegem-A.

Capobianco, B. M., Diefes-Dux, H. A., Mena, I., & Weller, J. (2011). What is an engineer? Implications of elementary school student conceptions for engineering education. Journal of Engineering Education, 100(2), 304-328.

Cerinsek, G., Hribar, T., Glodez, N., & Dolinsek, S. (2013). Which are my future career priorities and what influenced my choice of studying science, technology, engineering or mathematics? Some insights on educational choice—case of Slovenia. International Journal of Science Education, 35(17), 2999-3025.

Chachashvili-Bolotin, S., Milner-Bolotin, M., & Lissitsa, S. (2016). Examination of factors predicting secondary students’ interest in tertiary STEM education. International Journal of Science Education, 38(3), 366-390.

Chachashvili-Bolotin, S., Milner-Bolotin, M., & Lissitsa, S. (2016). Examination of factors predicting secondary students’ interest in tertiary STEM education. International Journal of Science Education, 38(3), 366-390.

Cheng, L., Antonenko, P. P., Ritzhaupt, A. D., & MacFadden, B. (2021). Exploring the role of 3D printing and STEM integration levels in students’ STEM career interest. British Journal of Educational Technology, 52, 1262-1278.

Chi, S., Wang, Z., Liu, X., & Zhu, L. (2017). Associations among attitudes, perceived difficulty of learning science, gender, parents’ occupation and students’ scientific competencies. International Journal of Science Education, 39(16), 2171-2177.

Christensen, R., & Knezek, G. (2017). Relationship of middle school student STEM interest to career intent. Journal of Education in Science, Environment and Health, 3(1), 1-13.

Christensen, R., Knezek, G., & Tyler-Wood, T. (2015). A retrospective analysis of STEM career interest among mathematics and science academy students. International Journal of Learning, Teaching and Educational Research, 10(1), 45-58.

Cohen, L., Manion, L., & Morrison, K. (2017) Research Methods in Education (8th Ed.). London: Routledge.

Creswell, J. W. (2012). Educational research: Planning, conducting, and evaluating quantitative and qualitative research. Boston: Pearson Education.

Crowther, D. T., & Bonnstetter, R. J. (1997). Science Experiences and Attitudes of Elementary Education Majors as They Experience Biology 295: A Multiple Case Study and Substantive Theory.

Dabney, K. P., Tai, R. H., & Scott, M. R. (2016). Informal science: family education, experiences, and initial interest in science. International Journal of Science Education, Part B, 6(3), 263-282.

Dong, Y., Wang, J., Yang, Y., & Kurup, P. M. (2020). Understanding intrinsic challenges to STEM instructional practices for Chinese teachers based on their beliefs and knowledge base. International Journal of STEM Education, 7(1), 1-12.

Dong, Y., Xu, C., Song, X., Fu, Q., Chai, C. S., & Huang, Y. (2019). Exploring the effects of contextual factors on in-service teachers’ engagement in STEM teaching. The Asia-Pacific Education Researcher, 28(1), 25-34.

Eccles, J.S., & Wigfield, A. (2002). Motivational beliefs, values and goals. Annual Reviews Psychology, 53, 109-132.

Eccles, J.S., Adler, T.F., Futterman, R., Goff, S.B., Kaczala, C.M., Meece, J.L., & Midgley, C. (1983). Expectancies, values and academic behaviours. In J.T. Spence (Ed.), Achievement and achievement motives: Psychological and sociological approaches (pp. 75–146). San Francisco: W.H. Friedman.

Fraenkel, J. R., Wallen, N. E., & Hyun, H. H. (2012). How to design and evaluate research in education. (8th Edition). New York: McGraw-Hill.

Geng, J., Jong, M. S. Y., & Chai, C. S. (2019). Hong Kong teachers’ self-efficacy and concerns about STEM education. The Asia-Pacific Education Researcher, 28(1), 35-45.

George, D., & Mallery, P. (2003). SPSS for Windows step by step: A simple guide and reference. 11.0 update (4th Ed.). Boston, United States of America: Allyn & Bacon.

Goddard, R. D., Hoy, W. K., & Hoy, A. W. (2000). Collective teacher efficacy: Its meaning, measure, and impact on student achievement. American educational research journal, 37(2), 479-507.

Guskey, T. R. & Passaro, P. D. (1994). Teacher Efficacy: A Study of Construct Dimensions. American Educational Research Journal, 31(3), 627-643.

Halim, L., Abd Rahman, N., Zamri, R., & Mohtar, L. (2018). The roles of parents in cultivating children's interest towards science learning and careers. Kasetsart Journal of Social Sciences, 39(2), 190-196.

Holland, J. L. (1985). Making vocational choices: A theory of vocational personalities and work environments. Englewood Cliffs: Prentice-Hall.

İnam, N. (2020). Öğretmenlere yönelik STEM tutum ölçeği geliştirme çalışması. Balıkesir Üniversitesi, Fen Bilimleri Enstitüsü, Yüksek Lisans Tezi. Balıkesir.

Ing, M., & Nylund-Gibson, K. (2013). Linking early science and mathematics attitudes to long-term science, technology, engineering, and mathematics career attainment: Latent class analysis with proximal and distal outcomes. Educational Research and Evaluation, 19(6), 510-524.

Işıksal-Bostan, M. (2016). A Longitudinal Study on Mathematics Teaching Efficacy: Which Factors (Un) Support the Development?. Eurasia Journal of Mathematics, Science and Technology Education, 12(8), 2085-2102.

Jamil, F. M., Linder, S. M., & Stegelin, D. A. (2018). Early childhood teacher beliefs about STEAM education after a professional development conference. Early Childhood Education Journal, 46(4), 409-417.

Kalaycı, Ş. (2010). SPSS uygulamalı çok değişkenli istatistik teknikleri. Ankara: Asil.

Kier, M. W., Blanchard, M. R., Osborne, J. W., & Albert, J. L. (2014). The development of the STEM career interest survey (STEM-CIS). Research in Science Education, 44(3), 461-481.

Kim, K. R., & Seo, E. H. (2018). The relationship between teacher efficacy and students' academic achievement: A meta-analysis. Social Behavior and Personality: an international journal, 46(4), 529-540.

Knowles, J., Kelley, T., & Holland, J. (2018). Increasing teacher awareness of STEM careers. Journal of STEM Education, 19(3), 47-55.

Koyunlu-Ünlü, Z., & Dökme, İ. (2020). Multivariate assessment of middle school students’ interest in STEM career: A profile from Turkey. Research in Science Education, 50(3), 1217-1231.

Koyunlu-Ünlü, Z., Dökme, I., & Ünlü, V. (2016). Adaptation of the science, technology, engineering, and mathematics career interest survey (STEM-CIS) into Turkish. Eurasian Journal of Educational Research, 63, 21-36.

Kundu, A., Bej, T., & Dey, K. N. (2021). Time to grow efficacious: effect of teacher efficacy on students’ classroom engagement. SN Social Sciences, 1(11), 1-24.

Kurup, P. M., Li, X., Powell, G., & Brown, M. (2019). Building future primary teachers’ capacity in STEM: based on a platform of beliefs, understandings and intentions. International Journal of STEM Education, 6(10), 1-14.

Lent, R. W., Brown, S. D., & Hackett, G. (1994). Toward a unifying social cognitive theory of career and academic interest, choice, and performance. Journal of Vocational Behavior, 45(1), 79-122.

Lichtenberger, E., & George-Jackson, C. E. (2013). Predicting high school students’ interest in majoring in a STEM field: Insight into high school students’ postsecondary plans. Journal of Career and Technical Education, 28(1), 19-38.

Margot, K. C., & Kettler, T. (2019). Teachers’ perception of STEM integration and education: a systematic literature review. International Journal of STEM education, 6(1), 1-16.

Mohamadi, F. S., & Asadzadeh, H. (2012). Testing the mediating role of teachers’ self-efficacy beliefs in the relationship between sources of efficacy information and students achievement. Asia Pacific Education Review, 13(3), 427-433.

Moore, T. J., Stohlmann, M. S., Wang, H. H., Tank, K. M., Glancy, A. W., & Roehrig, G. H. (2014). Implementation and integration of engineering in K-12 STEM education. In Engineering in pre-college settings: Synthesizing research, policy, and practices (pp. 35-60). Purdue University Press.

Murcia, K., Pepper, C. & Williams, P. J. (2020). Youth STEM career choices: What’s influencing secondary students’ decision making. Issues in Educational Research, 30(2), 593-611.

Nadelson, L. S., & Seifert, A. L. (2017). Integrated STEM defined: Contexts, challenges, and the future. The Journal of Educational Research, 110(3), 221-223.

Nadelson, L. S., Callahan, J., Pyke, P., Hay, A., Dance, M., & Pfiester, J. (2013). Teacher STEM perception and preparation: Inquiry-based STEM professional development for elementary teachers. The Journal of Educational Research, 106(2), 157-168.

Nugent, G., Barker, B., Welch, G., Grandgenett, N., Wu, C. R., & Nelson, C. (2015). A model of factors contributing to STEM learning and career orientation. International Journal of Science Education, 37(7), 1067-1088.

OECD. (2014). Do parents’ occupations have an impact on student performance? Paris, France: OECD.

Özdemir, A., Yaman, C., & Vural, R. A. (2018). STEM uygulamaları öğretmen öz-yeterlik ölçeğinin geliştirilmesi: Bir geçerlik ve güvenirlik çalışması. Adnan Menderes Üniversitesi Sosyal Bilimler Enstitüsü Dergisi, 5(2), 93-104.

Pajares, M. F. (1992). Teachers’ beliefs and educational research: Cleaning up a messy construct. Review of educational research, 62(3), 307-332.

Paulson, P. (2009). Developing quality through improved attitudes toward science and science teaching. In annual meeting of the American Association of Colleges for Teacher Education Online. Retrieved from http://www. allacademic. com/meta/p35803_index. html.

Regan, E., & DeWitt, J. (2015). Attitudes, interest and factors influencing STEM enrolment behaviour: An overview of relevant literature. In Henriksen, E. K., Dillon, J., & Ryder, J. (Eds.). Understanding student participation and choice in science and technology education (p.p. 63-88). Dordrecht: Springer.

Rimm-Kaufman, S. E., & Sawyer, B. E. (2004). Primary-grade teachers’ self-efficacy beliefs, attitudes toward teaching, and discipline and teaching practice priorities in relation to the” responsive classroom” approach. The Elementary School Journal, 104(4), 321-341.

Sahin, A., Oren, M., Willson, V., Hubert, T., & Capraro, R. M. (2015). Longitudinal analysis of TSTEM academies: How do Texas inclusive STEM academies (T-STEM) perform in Mathematics, Science, and Reading? International Online Journal of Educational Sciences, 7(4), 11-21.

Sarac, A., & Tutak, F. A. (2017). The relationship between teacher efficacy, and students' trigonometry self-efficacy and achievement. International Journal for Mathematics Teaching and Learning, 18(1), 66-83.

Sjaastad, J. (2012). Sources of inspiration: The role of significant persons in young people’s choice of science in higher education. International Journal of Science Education, 34(10), 1615-1636.

Swars, S. L. (2005). Examining perceptions of mathematics teaching effectiveness among elementary preservice teachers with differing levels of mathematics teacher efficacy. Journal of instructional Psychology, 32(2), 139-147.

Tabachnick, B. G., & Fidel, L. S. (2019). Using multivariate statistics (7th Ed.). Boston: Pearson.

Tasdemir, A., Kartal, T., & Ozdemir, A. M. (2014). Using science centers and museums for teacher training in Turkey. The Asia-Pacific Education Researcher, 23(1), 61-72.

Tey, T. C. Y., Moses, P., & Cheah, P. K. (2020). Teacher, parental and friend influences on STEM interest and career choice intention. Issues in Educational Research, 30(4), 1558-1575.

Thibaut, L., Knipprath, H., Dehaene, W., & Depaepe, F. (2018). How school context and personal factors relate to teachers’ attitudes toward teaching integrated STEM. International Journal of Technology and Design Education, 28(3), 631-651.

Tschannen-Moran, M., & Hoy, A. W. (2001). Teacher efficacy: Capturing an elusive construct. Teaching and teacher education, 17(7), 783-805.

TUSIAD. (2022). 2023’e doğru Türkiye’de STEM gereksinimi [STEM requirements in Turkey towards to 2023]. Retrieved from: https://www.pwc.com.tr/tr/gundem/dijital/2023e-dogru-turkiyede-stem-gereksinimi.html on 11 January 2022.

Tyler-Wood, T., Ellison, A., Lim, O., & Periathiruvadi, S. (2012). Bringing up girls in science (BUGS): The effectiveness of an after-school environmental science program for increasing female students’ interest in science careers. Journal of Science Education and Technology, 21(1), 46-55.

Wang, H., Moore, T. J., Roehrig, G. H., & Park, M. S. (2011). STEM Integration: Teacher Perceptions and Practice. Journal of Pre-College Engineering Education Research (J-PEER), 1(2), Article 2.

Wang, M. T., & Degol, J. (2013). Motivational pathways to STEM career choices: Using expectancy–value perspective to understand individual and gender differences in STEM fields. Developmental Review, 33(4), 304-340.

Xie, Y., Fang, M., & Shauman, K. (2015). STEM education. Annual review of sociology, 41, 331-357.