___

• Abbott, M. L. (2017). Using statistics in the social and health sciences with SPSS and Excel. Hoboken, New Jersey: John Wiley & Sons.
• Abu-Bader, S. H. (2021). Using statistical methods in social science research: With a complete SPSS guide (3rd edition). Oxford, UK: Oxford University Press.
• Aduwa-Ogiegbaen, S. E., & Iyamu, E. O. S. (2005). Using information and communication technology in secondary schools in Nigeria: Problems and prospects. Journal of Educational Technology & Society, 8(1), 104-112.
• Aesaert, K., & van Braak, J. (2015). Gender and socioeconomic related differences in performance based ICT competences. Computers & Education, 84, 8-25.
• Akgün, F. (2020). Öğretmen adaylarının bilgi ve iletişim teknolojileri yeterlikleri ve bilgi işlemsel düşünme becerilerinin çeşitli değişkenler açısından değerlendirilmesi [An evaluation on pre-service teacher’s information and communications technology competency and computational thinking skills in terms of different variables]. Trakya Üniversitesi Sosyal Bilimler Dergisi [Trakya University Journal of Social Science], 22(1), 629-654.
• Aldrich, J. O., & Cunningham, J. B. (2016). Using IBM SPSS statistics: An interactive hands-on approach (2nd edition). Thousand Oaks, California: Sage Publications, Inc.
• Almerich, G., Orellana, N., Suárez-Rodríguez, J., & Díaz-García, I. (2016). Teachers’ information and communication technology competences: A structural approach. Computers & Education, 100, 110-125.
• Alnıak, S., & Ogan Bekiroglu, F. (2019). Examintion of integrated STEM education in physics: Students’ attitude towards STEM. The Eurasia Proceedings of Educational and Social Sciences, 14, 55-59.
• Al-Zaidiyeen, N. J., Mei, L. L., & Fook, F. S. (2010). Teachers' attitudes and levels of technology use in classrooms: The case of Jordan Schools. International Education Studies, 3(2), 211-218.
• Amini, C. M., & Oluyide, O. P. (2020). Analysis of ICT competencies among distance learning students in selected study centres of the National Open University of Nigeria. Journal of Learning for Development, 7(1), 78-89.
• Aydogan Yenmez, A., Gökce, S., Aydede, M. N., & Çelik,T. (2021). Investigation of pre-service teachers' awareness of STEM and STEM teaching intention. International Online Journal of Education and Teaching, 8(1), 250-260.
• Ayvacı, H. Ş., Alaca, M. B., & Er Nas, S. (2020). Fen bilimleri dersi öğretim programında yeniden yapılandırılan fen ve mühendislik uygulamalarının öğretmen görüşlerine dayalı olarak değerlendirilmesi [Evaluation of science and engineering applications restructured in science curriculum based on teacher view]. Öğretim Teknolojileri ve Öğretmen Eğitimi Dergisi [Journal of Instructional Technologies & Teacher Education], 9(1), 28-41.
• Bandura, A. (2006). Guide for creating self-efficacy scales. In F. Pajares & T. Urdan (Eds.), Self-efficacy beliefs of adolescents (pp. 307-337). Greenwich, Connecticut: IAP- Information Age Publishing, Inc.
• Barak, M. (2014). Closing the gap between attitudes and perceptions about ICT-enhanced learning among pre-service STEM teachers. Journal of Science Education and Technology, 23(1), 1-14.
• Baran, M., Baran, M., Aslan Efe, H., & Maskan, A. (2020). Fen alanları öğretmenleri ve öğretmen adaylarının FeTeMM farkındalık düzeylerinin çeşitli değişkenlere göre incelenmesi [Examining STEM awareness level of science teachers and prospective science teachers in terms of various variables]. Amasya Üniversitesi Eğitim Fakültesi Dergisi [Amasya Education Journal], 9(1), 1-29.
• Bay, Y., Bay, D. N., & Hartman, D. K. (2021). Examining the preschool and primary school teachers’ perception of self-confidence about their TPACK in Turkey. International Online Journal of Primary Education, 10(2), 287-307.
• Bingimlas, K. A. (2009). Barriers to the successful integration of ICT in teaching and learning environments: A review of the literature. Eurasia Journal of Mathematics, Science and Technology Education, 5(3), 235-245.
• Birzina, R., & Pigozne, T. (2020). Technology as a tool in STEM teaching and learning. In V. Dislere (Eds.), The Proceedings of the 13th International Scientific Conference Rural Environment. Education. Personality. (REEP), 13. Jelgava: Latvia University of Life Sciences and Technologies, 219-227.
• Blickenstaff, J. C. (2005). Women and science careers: Leaky pipeline or gender filter? Gender and Education, 17(4), 369–386.
• 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.
• Browne, M. W., & Cudeck, R. (1992). Alternative ways of assessing model fit. Sociological Methods & Research, 21(2), 230-258.
• Bryan, L. A., Moore, T. J., Johnson, C. C., & Roehrig, G. H. (2016). The emergence of STEM. In C. C. Johnson, E. E. Peters-Burton, & T. J. Moore (Eds.), STEM road map a framework for integrated STEM education (pp. 23-38). New York: Routledge.
• Buabeng-Andoh, C., & Issifu, Y. (2015). Implementation of ICT in learning: A study of students in Ghanaian secondary schools. Procedia-Social and Behavioral Sciences, 191, 1282-1287.
• Buyruk, B., & Korkmaz, Ö. (2016). Teacher candidates’ STEM awareness levels. Participatory Educational Research, Special Issue 2016-III, 272-279.
• Bybee, R. W. (2010). Advancing STEM education: A 2020 vision. Technology and Engineering Teacher, 70(1), 30-35.
• Byrne, B. M. (1995). One application of structural equation modeling from two perspectives: Exploring the EQS and LISREL strategies. In R. H. Hoyle (Eds.), Structural equation modeling: Concepts, ıssues, and applications (pp. 138–157). Thousand Oaks, CA: Sage.
• Carnevale, A. P., Smith, N., & Melton, M. (2011). STEM: Science, technology, engineering, mathematics. Washington, DC: Georgetown University Center on Education and the Workforce. Retrieved from https://cew.georgetown.edu/cew-reports/stem/
• Ceci, S. J., Williams, W. M., & Barnett, S. M. (2009). Women's underrepresentation in science: Sociocultural and biological considerations. Psychological Bulletin, 135(2), 218-261.
• Chen, W., Lim, C., & Tan, A. (2010). Pre-service teachers’ ICT experiences and competencies: New generation of teachers in digital age. In S. L. Wong, et al. (Eds.), Proceedings of the 18th International Conference on Computers in Education (pp. 631-638). Putrajaya, Malaysia: Asia-Pacific Society for Computers in Education.
• Cheryan, S., Ziegler, S. A., Montoya, A. K., & Jiang, L. (2017). Why are some STEM fields more gender balanced than others? Psychological Bulletin, 143(1), 1-35.
• Chiu, A., Price, C. A., & Ovrahim, E. (2015, April). Supporting elementary and middle school STEM education at the whole-school level: A review of the literature. In NARST 2015 Annual Conference, April 11-14 2015, Chicago, IL. Museum of Science and Industry. Retrieved from https://www.msichicago.org/education/professional-development/science-leadership/school-partners/
• 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.
• Cohen, A. (1996). On the discriminant validity of the Meyer and Allen measure of organizational commitment: How does it fit with the work commitment construct? Educational and Psychological Measurement, 56(3), 494-503.
• Cole, D. A. (1987). Utility of confirmatory factor analysis in test validation research. Journal of Consulting and Clinical Psychology, 55(4), 584–594.
• Council of Higher Education [Yükseköğretim Kurulu] (2018). New Teacher Training Undergraduate Programs [Yeni Öğretmen Yetiştirme Lisans Programları], Classroom Teaching Undergraduate Program [Sınıf Öğretmenliği Lisans Programı]. Retrieved from https://www.yok.gov.tr/Documents/Kurumsal/egitim_ogretim_dairesi/Yeni-Ogretmen-Yetistirme-Lisans-Programlari/Sinif_Ogretmenligi_Lisans_Programi09042019.pdf
• Creswell, J. (2015). Educational research: Planning, conducting, and evaluating quantitative and qualitative research (5th edition). Upper Saddle River, NJ: Pearson Education.
• Cronk, B. C. (2020). How to use SPSS: A step-by-step guide to analysis and interpretation (11th edition). New York, NY: Routledge.
• Çavuş, H., Özgüner, Ö., & Güler, Ç. (2021). Bilgisayar ve öğretim teknolojileri öğretmen adaylarının STEM (FeTeMM) eğitimine yönelik görüş ve tutumları [Computer education and instructional technology teacher candidates’ ideas and attitudes towards STEM education]. Elektronik Eğitim Bilimleri Dergisi [Electronic Journal of Education Sciences], 10(20), 237-256.
• Dabney, K. P., Tai, R. H., Almarode, J. T., Miller-Friedmann, J. L., Sonnert, G., Sadler, P. M., & Hazari, Z. (2012). Out-of-school time science activities and their association with career interest in STEM. International Journal of Science Education, Part B: Communication and Public Engagement, 2(1), 63-79.
• Danner, R. B., & Pessu, C. O. A. (2013). A survey of ICT competencies among students in teacher preparation programmes at the University of Benin, Benin City, Nigeria. Journal of Information Technology Education: Research, 12, 33-49.
• Dedetürk, A., Saylan Kırmızıgül, A., & Kaya, H. (2020). “Ses” konusunun STEM etkinlikleri ile öğretiminin başarıya etkisi [The Effect of STEM Activities on Students’ Achievement in “Sound” Subject]. Pamukkale Üniversitesi Eğitim Fakültesi Dergisi [Pamukkale University Journal of Education], 49, 134-161.
• Değirmenci, S. (2020). STEM eğitimi almış öğretmenlerin STEM öz yeterliklerinin ve uygulamalarında teknoloji ve mühendislik entegrasyonu açısından yaşadıkları sorunların belirlenmesi [Identifying self-suffiency of the teachers having STEM education and their problems in applications with regard to the integration of technology and engineering]. (Master’s thesis). Marmara University, İstanbul.
• Demir Başaran, S., & Temircan, S. (2018). Sınıf öğretmeni adaylarının STEM öğretimi yönelimleri [Elementary pre-service teachers’ STEM teaching orientation]. Uluslararası Sosyal Araştırmalar Dergisi [The Journal of International Social Research], 11(61), 659-667.
• Ejiwale, J. A. (2013). Barriers to successful implementation of STEM education. Journal of Education and Learning (EduLearn), 7(2), 63-74.
• Fraenkel, J. R., Wallen, N. E., & Hyun, H. H. (2012). How to design and evaluate research in education (8th edition). New York: McGraw Hill.
• Frykholm, J., & Glasson, G. (2005). Connecting science and mathematics instruction: Pedagogical context knowledge for teachers. School Science and Mathematics, 105(3), 127-141.
• Furner, J. M., & Kumar, D. D. (2007). The mathematics and science integration argument: A stand for teacher education. Eurasia Journal of Mathematics, Science and Technology Education, 3(3), 185-189.
• Gastelú, C. A. T., Kiss, G., & Domínguez, A. L. (2015). Level of ICT competencies at the university. Procedia-Social and Behavioral Sciences, 174, 137-142.
• George, D., & Mallery, P. (2020). IBM SPSS statistics 26 step by step: A simple guide and reference (16th edition). New York, NY: Routledge.
• Gerlach, H. E. (2020). The impact of integrated STEM education on student achievement in magnet schools. (Doctoral dissertation). National Louis University, Chicago, IL.
• Ghavifekr, S., & Rosdy, W. A. W. (2015). Teaching and learning with technology: Effectiveness of ICT integration in schools. International Journal of Research in Education and Science, 1(2), 175-191.
• Goktas, Y., & Demirel, T. (2012). Blog-enhanced ICT courses: Examining their effects on prospective teachers’ ICT competencies and perceptions. Computers & Education, 58(3), 908-917.
• Goktas, Y., Yildirim, Z., & Yildirim, S. (2009). Investigation of K-12 teachers’ ICT competencies and the contributing factors in acquiring these competencies. The New Educational Review, 17(1), 276-294.
• Günbatar, M. S., & Bakırcı, H. (2019). STEM teaching intention and computational thinking skills of pre-service teachers. Education and Information Technologies, 24(2), 1615-1629.
• Gündüz, Ş. (2020). Investigation of the relationship between pre-service teachers' perceptions of education and support for ICT and ICT competencies. Malaysian Online Journal of Educational Technology, 8(2), 28-42.
• Güngör, A. (2021). Öğretmen ve öğretmen adaylarının bütünleşik STEM eğitimine yönelik teknolojik pedagojik alan bilgilerinin belirlenmesi [Determination of technological pedagogical content knowledge for integrated STEM education of teachers and prospective teachers]. (Master’s thesis). Alanya Alaaddin Keykubat University, Alanya.
• Hacıömeroğlu, G. (2018). Sınıf öğretmeni adaylarının fen, teknoloji, mühendislik ve matematik (FeTeMM) öğretimi yönelim düzeylerinin incelenmesi [Examining elementary pre-service teachers’ science, technology, engineering, and mathematics (STEM) teaching intention]. International Online Journal of Educational Sciences, 10(1), 183-194.
• Hacıömeroğlu, G., & Bulut, A. S. (2016), Entegre FeTeMM öğretimi yönelim ölçeği Türkçe formunun geçerlik ve güvenirlik çalışması [Integrative STEM teaching intention questionnaire: A validity and relaibility study of the Turkish form]. Eğitimde Kuram ve Uygulama [Journal of Theory and Practice in Education], 12(3), 654-669.
• Haddad, W. D., & Draxler, A. (2002). The dynamics of technologies for education. In W. D. Haddad & A. Draxler (Eds.), Technologies for education: Potentials, parameters, and prospects (pp. 2-17). Paris: UNESCO and Washington, DC: Academy for Educational Development.
• Hammond, M., Reynolds, L., & Ingram, J. (2011). How and why do student teachers use ICT? Journal of Computer Assisted Learning, 27(3), 191-203.
• Hatlevik, O. E., Throndsen, I., Loi, M., & Gudmundsdottir, G. B. (2018). Students’ ICT self-efficacy and computer and information literacy: Determinants and relationships. Computers & Education, 118, 107-119.
• Hayes, A. R., & Bigler, R. S. (2013). Gender-related values, perceptions of discrimination, and mentoring in STEM graduate training. International Journal of Gender, Science and Technology, 5(3), 254-280.
• Haznedar, Ö. (2012). Üniversite öğrencilerinin bilgi ve iletişim teknolojileri becerilerinin ve e-öğrenmeye yönelik tutumlarının farklı değişkenler açısından incelenmesi [The investigation of undergraduate students' information and communication technology skills and attitudes to e-learning in terms of different variables]. (Master’s thesis). Dokuz Eylül University, İzmir.
• Hernandez, P. R., Bodin, R., Elliott, J. W., Ibrahim, B., Rambo-Hernandez, K. E., Chen, T. W., & de Miranda, M. A. (2014). Connecting the STEM dots: Measuring the effect of an integrated engineering design intervention. International Journal of Technology and Design Education, 24(1), 107-120.
• Hérold, J. F., & Ginestié, J. (2017). Using ICT in STEM education: A help or a hindrance to student learning? In I. Levin & D. Tsybulsky (Eds.), Digital tools and solutions for inquiry-based STEM learning (pp. 197- 220). Hershey, PA: IGI Global.
• Herschbach, D. R. (2011). The STEM initiative: Constraints and challenges. Journal of STEM Teacher Education, 48(1), 96-122.
• Hew, T. S., & Leong, L. Y. (2011). An empirical analysis of Malaysian pre-university students' ICT competency gender differences. International Journal of Network and Mobile Technologies, 2(1), 15-29.
• Ho, R. (2018). Understanding statistics for the social sciences with IBM SPSS. Boca Raton: CRC Press.
• Hosein, A., Ramanau, R., & Jones, C. (2010). Learning and living technologies: A longitudinal study of first‐year students’ frequency and competence in the use of ICT. Learning, Media and Technology, 35(4), 403-418.
• Hu, L. T., & Bentler, P. M. (1999). Cutoff criteria for fit indexes in covariance structure analysis: Conventional criteria versus new alternatives. Structural Equation Modeling: A Multidisciplinary Journal, 6(1), 1-55.
• Huri, N. H. D., & Karpudewan, M. (2019). Evaluating the effectiveness of integrated STEM-lab activities in improving secondary school students’ understanding of electrolysis. Chemistry Education Research and Practice, 20(3), 495-508.
• Jolly, A. (2017). STEM by design strategies and activities for grades 4–8. New York: Routledge.
• Kanematsu, H., & Barry, D. M. (2016). STEM and ICT education in intelligent environments. Switzerland: Springer.
• Kanny, M. A., Sax, L. J., & Riggers-Piehl, T. A. (2014). Investigating forty years of STEM research: How explanations for the gender gap have evolved over time. Journal of Women and Minorities in Science and Engineering, 20(2), 127-148.
• Karakaya, F., Avgın, S. S., & Yılmaz, M. (2018). Ortaokul öğrencilerinin fen-teknoloji-mühendislik-matematik (FeTeMM) mesleklerine olan ilgileri [Middle school students' interest in science-technology-engineering and mathematics (STEM) professions]. Ihlara Eğitim Araştırmaları Dergisi [Ihlara Journal of Educational Research], 3(1), 36-53.
• Kareem, J., Thomas, R. S., & Nandini, V. S. (2022). A conceptual model of teaching efficacy and beliefs, teaching outcome expectancy, student technology use, student engagement, and 21st-century learning attitudes: A STEM education study. Interdisciplinary Journal of Environmental and Science Education, 18(4), 1-11.
• Karisan, D., Macalalag, A., & Johnson, J. (2019). The effect of methods course on pre-service teachers' awareness and ıntentions of teaching science, technology, engineering, and mathematics (STEM) subject. International Journal of Research in Education and Science, 5(1), 22-35.
• Kennedy, T. J., & Odell, M. R. L. (2014). Engaging students in STEM education. Science Education International, 25(3), 246-258.
• Kennewell, S., Parkinson, J., & Tanner, H. (2000). Developing the ICT-capable school. London: Routledge Falmer.
• Koehler, C., Binns, I. C., & Bloom, M. A. (2016). The emergence of STEM. In C. C. Johnson, E. E. Peters-Burton & T. J. Moore (Eds.), STEM road map a framework for integrated STEM education (pp. 13-22). New York: Routledge.
• Lee, A. C. K. (2003). Undergraduate students' gender differences in IT skills and attitudes. Journal of Computer Assisted Learning, 19(4), 488-500.
• Lin, K.-Y., & Williams, P. J. (2016). Taiwanese preservice teachers’ science, technology, engineering, and mathematics teaching intention. International Journal of Science and Mathematics Education, 14(6), 1021-1036.
• Lodico, M. G., Spaulding, D. T., & Voegtle, K. H. (2010). Methods in educational research: From theory to practice (2nd edition). San Francisco, CA: John Wiley & Sons.
• Madigan, E. M., Goodfellow, M., & Stone, J. A. (2007). Gender, perceptions, and reality: Technological literacy among first-year students. ACM SIGCSE Bulletin, 39(1), 410-414.
• Mahoney, M. P. (2009). Student attitude toward STEM: Development of an instrument for high school STEM-based programs. (Doctoral dissertation). The Ohio State University, Columbus, OH.
• Moore, T. J., & Smith, K. A. (2014). Advancing the state of the art of STEM integration. Journal of STEM Education: Innovations and Research, 15(1), 5-10.
• Nadelson, L. S., & Seifert, A. L. (2017). Integrated STEM defined: Contexts, challenges, and the future. The Journal of Educational Research, 110(3), 221-223.
• National Academy of Engineering ve National Research Council [NAE & NRC]. (2009). Engineering in K-12 education: Understanding the status and improving the prospects. Washington: National Academies Press.
• National Academy of Engineering ve National Research Council [NAE & NRC]. (2014). STEM integration in K–12 education: Status, prospects, and an agenda for research. Washington, DC: National Academies Press.
• National Research Council [NRC]. (2011). Successful K-12 STEM education: Identifying effective approaches in science, technology, engineering, and mathematics. Washington: National Academies Press.
• Nimmesgern, H. (2016). Why are women underrepresented in STEM fields? Chemistry: A European Journal, 22(11), 3529–3530.
• O’Brien, L. T., Blodorn, A., Adams, G., Garcia, D. M., & Hammer, E. (2015). Ethnic variation in gender-STEM stereotypes and STEM participation: An intersectional approach. Cultural Diversity and Ethnic Minority Psychology, 21(2), 169–180.
• Ottestad, G. (2010). Innovative pedagogical practice with ICT in three Nordic countries–differences and similarities. Journal of Computer Assisted Learning, 26(6), 478-491.
• Pajares, F. (2005). Gender differences in mathematics self-efficacy beliefs. In A. M. Gallagher & J. C. Kaufman (Eds.), Gender differences in mathematics: An integrative psychological approach (pp. 294-315). Boston: Cambridge University Press.
• Pallant, J. (2001). SPSS survival manual: A step by step guide to data analysis using SPSS for Windows (Version 10). Crows Nest, NSW: Allen & Unwin.
• Patten, M. L., & Newhart, M. (2018). Understanding research methods: An overview of the essentials (10th edition). New York, NY: Routledge.
• Pearson, G. (2017). National academies piece on integrated STEM. The Journal of Educational Research, 110(3), 224-226.
• Piatek-Jimenez, K., Cribbs, J., & Gill, N. (2018). College students’ perceptions of gender stereotypes: Making connections to the underrepresentation of women in STEM fields. International Journal of Science Education, 40(12), 1-23.
• Pullen, D. (2015). The influence of the home learning environment on middle school students’ use of ICT at school. Australian Educational Computing, 30(1).
• Reinking, A., & Martin, B. (2018). The gender gap in STEM felds: Theories, movements, and ideas to engage girls in STEM. Journal of New Approaches in Educational Research, 7(2), 148–153.
• Sadler, P. M., Sonnert, G., Hazari, Z., & Tai, R. (2012). Stability and volatility of STEM career interest in high school: A gender study. Science Education, 96(3), 411-427.
• Sanders, M. (2009). STEM, STEM education, STEMmania. The Technology Teacher, 68(4), 20–26.
• Saracaloğlu, A. S., Yenice, N., & Özden, B. (2013). Fen bilgisi öğretmen adaylarının fen ve teknoloji okuryazarlığına ilişkin öz yeterlik algıları ile fene yönelik tutumları arasındaki ilişki [Relationship between self efficacy perceptions towards science and technology literacy with attitudes towards science of science teachers’]. International Journal of New Trends in Arts, Sports & Science Education, 2(1), 58-69.
• Sarican, G., & Akgunduz, D. (2018). The impact of integrated STEM education on academic achievement, reflective thinking skills towards problem solving and permanence in learning in science education. Cypriot Journal of Educational Sciences, 13(1), 94-107.
• Saucerman, J., & Vasquez, K. (2014). Psychological barriers to STEM participation for women over the course of development. Adultspan Journal, 13(1), 46–64.
• Schumacker, R. E., & Lomax, R. G. (2004). A beginner’s guide to structural equation modeling (2nd edition). Mahwah, New Jersey: Lawrence Erlbaum Associates.
• Sezen-Gultekin, G., Hamutoglu, N. B., & Topal, M. (2021). Relationship between teacher efficacy and information and communication technology competencies of pre-service teachers. Khazar Journal of Humanities and Social Sciences, 24(3), 43-61.
• Shaughnessy, J. M. (2013). Mathematics in a STEM Context. Mathematics Teaching in the Middle School, 18(6), 324.
• Sipilä, K. (2014). Educational use of information and communications technology: Teachers’ perspective. Technology, Pedagogy and Education, 23(2), 225-241.
• Soylu Yalcinkaya, N., & Adams, G. (2020). A cultural psychological model of cross-national variation in gender gaps in STEM participation. Personality and Social Psychology Review, 24(4), 345–370.
• Stevens, J. P. (2009). Applied multivariate statistics for the social sciences (5th edition). New York, NY: Routledge.
• Stohlmann, M., Moore, T. J., & Roehrig, G. H. (2012). Considerations for teaching integrated STEM education. Journal of Pre-College Engineering Education Research (J-PEER), 2(1), 28-34.
• Suárez-Rodríguez, J., Almerich, G., Orellana, N., & Díaz-García, I. (2018). A basic model of integration of ICT by teachers: Competence and use. Educational Technology Research and Development, 66(5), 1165-1187.
• Şad, S. N., & Nalçacı, Ö. İ. (2015). Öğretmen adaylarının eğitimde bilgi ve iletişim teknolojilerini kullanmaya ilişkin yeterlilik algıları [Prospective teachers’ perceived competencies about integrating information and communication technologies into education]. Mersin Üniversitesi Eğitim Fakültesi Dergisi [Mersin University Journal of the Faculty of Education], 11(1), 177-197.
• Şen, C., & Timur, B. (2018). Öğretmen adaylarının entegre FeTeMM öğretimine yönelimleri ve teknolojiye yönelik tutumları [Investigating the tendencies of prospective teachers towards integrated STEM teaching and their attitudes towards technology]. İstanbul Aydın Üniversitesi Eğitim Fakültesi Dergisi, 4(2), 123-142.
• Talebian, S., Mohammadi, H. M., & Rezvanfar, A. (2014). Information and communication technology (ICT) in higher education: Advantages, disadvantages, conveniences and limitations of applying e-learning to agricultural students in Iran. Procedia-Social and Behavioral Sciences, 152, 300-305.
• Taşpolat, A. (2016). Perception of prospective teachers’ competencies about information and communication technology (ICT). (Master's thesis). Eastern Mediterranean University, Gazimağusa, North Cyprus.
• Tekerek, B., & Karakaya, F. (2018). STEM education awareness of pre-service science teachers. International Online Journal of Education and Teaching, 5(2), 348-359.
• Tezci, E. (2010). Attitudes and knowledge level of teachers in ICT use: The case of Turkish teachers. International Journal of Human Sciences, 7(2), 19-44.
• 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.
• Tobishima, S. (2020). Gender and socioeconomic differences in adolescents' perceived information and communication technology (ICT) competencies. Journal of Socio-Informatics, 13(1), 1-13.
• Tondeur, J., Aesaert, K., Prestridge, S., & Consuegra, E. (2018). A multilevel analysis of what matters in the training of pre-service teacher's ICT competencies. Computers & Education, 122, 32-42.
• Tondeur, J., Pareja Roblin, N., van Braak, J., Voogt, J., & Prestridge, S. (2017). Preparing beginning teachers for technology integration in education: Ready for take-off? Technology, Pedagogy and Education, 26(2), 157-177.
• Tondeur, J., Sinnaeve, I., van Houtte, M., & van Braak, J. (2011). ICT as cultural capital: The relationship between socioeconomic status and the computer-use profile of young people. New Media & Society, 13(1), 151-168.
• Ulku Kan, A., & Murat, A. (2018). Investigation of prospective science teachers' 21st century skill competence perceptions and attitudes toward STEM. International Online Journal of Educational Sciences, 10(4), 251-272.
• Valasidou, A., & Bousiou-Makridou, D. (2008). The impact of ICT’s in education: The case of University of Macedonia students. Journal of Business Case Studies, 4(3), 29-34.
• Vitanova, V., Atanasova-Pachemska, T., & Pachemska, S. (2014). Factors affecting the frequency of ICT usage in primary schools teaching. The Eurasia Proceedings of Educational and Social Sciences, 1, 461-468.
• Volman, M., & van Eck, E. (2001). Gender equity and information technology in education: The second decade. Review of Educational Research, 71(4), 613-634.
• Watt, H. M. G., Richardson, P. W., & Devos, C. (2013). (How) does gender matter in the choice of a STEM teaching career and later teaching behaviours? International Journal of Gender, Science and Technology, 5(3), 187-206.
• White, D. W. (2014). What is STEM education and Why is it important? Florida Association of Teacher Educators Journal, 1(14), 1-9.
• Wu, Y. T., & Anderson, O. R. (2015). Technology-enhanced STEM (science, technology, engineering, and mathematics) education. Journal of Computers in Education, 2(3), 245-249.
• Xie, Y., Fang, M., & Shauman, K. (2015). STEM education. Annual Review of Sociology, 41, 331–357.
• Yusuf, M. O. (2005). Information and communication technology and education: Analysing the Nigerian national policy for information technology. International Education Journal, 6(3), 316-321.
• Yusuf, M. O., & Balogun, M. R. (2011). Student-teachers' competence and attitude towards information and communication technology: A case study in a Nigerian University. Contemporary Educational Technology, 2(1), 18-36.