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The Effects of Design-Based Learning Applications on STEM Perceptions Development of Pre-Service Science Teachers

Year 2020, , 231 - 265, 25.12.2020
https://doi.org/10.33711/yyuefd.691585

Abstract

The aim of this study is to examine the effects of design-based learning applications on development of pre-service science teachers’ STEM perceptions.
The research, one group pretest-posttest-following test research design was used. Participants were 36 pre-service science teachers who enrolled to the Dede Korkut Faculty of Education at Kafkas University in 2017-2018 academic year spring semester. In the experimentation process, the pre-service science teachers studied about the design problems as group in the course of ‘Special Teaching Methods-I’. Data was gathered by ‘STEM Competence Scale’, ‘Assessment Form of STEM Domain Knowledge’, and ‘Interview Form’. Whereas the quantitative data was gathered through pretest, posttest and retention test, the qualitative data was gathered just after the experimentation process. One-way ANOVA for repeated measures was used to analyze the quantitative data and content analysis approach was used to analyze the qualitative data. The findings based on the quantitative data showed that design-based learning activities significantly enhanced pre-service science teachers’ STEM competencies, and domain knowledge related with STEM disciplines. Furthermore, the results obtained from the qualitative data revealed that design-based learning activities affected the pre-service science teachers’ STEM perceptions, expectations of STEM career, skill development and how to use a student’s learning.

References

  • Adedokun, O. A., Bessenbacher, A. B., Parker, L. C., Kirkham, L. L., & Burgess, W. D. (2013). Research skills and STEM undergraduate research students' aspirations for research careers: Mediating effects of research self‐efficacy. Journal of Research in Science Teaching, 50, 940–951. Akgündüz, D., Aydeniz, M., Çakmakçı, G., Çavaş, B., Çorlu, M. S., Öner, T., & vd. (2015). STEM eğitimi Türkiye raporu: Günün modası mı yoksa gereksinim mi? [A report on STEM Education in Turkey: A provisional agenda or a necessity?] [White Paper]. İstanbul, Turkey: Aydın Üniversitesi. Retrieved from http://www.aydin.edu.tr/belgeler/IAUSTEM-Egitimi-Turkiye-Raporu2015.pdf Allendoerfer, C., Wilson, D., Kim, M. J., & Burpee, E. (2014). Mapping beliefs about teaching to patterns of instruction within science, technology, engineering, and mathematics. Teaching in Higher Education, 19(7), 758–771. 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. Arslanhan, H. (2019). Tasarım temelli öğrenme uygulamalarının fen bilimleri öğretmen adaylarının STEM anlayışlarını geliştirmeye etkisi. (Yayımlanmamış yüksek lisans tezi). Kafkas Üniversitesi, Fen Bilimleri Enstitüsü, Kars. Avery, Z. K., & Reeve, E. M. (2013). Developing effective STEM professional development programs. Journal of Technology Education, 25(1), 55–69. Asunda, P. A., & Hill, R. B. (2007). Critical features of engineering design in technology education. Journal of Industrial Teacher Education, 44(1), 25–48. Awad, N., & Barak, M. (2018). Pre-service science teachers learn a science, technology, engineering and mathematics (STEM)-oriented program: The case of sound, waves and commication systems. EURASIA Jornal of Mathematics, Science and Technology Education, 14(4), 1431-1451. Ayaz, E. & Sarikaya, R. (2019). The effect of engineering design-based science teaching on the perceptions of classroom teacher candidates towards STEM disciplines. International Journal of Progressive Education, 15(3), 13-27. Aydın-Günbatar, S. A., Tarkın-Çelikkıran, A., Kutucu, E. S., & Ekiz-Kıran, B. (2018). The influence of a design-based elective stem course on pre-service chemistry teachers’ content knowledge, STEM conceptions, and engineering views. Chemistry Education Research and Practice, 19(3), 954-972. doi: 10.1039/C8RP00128. Bagiati, A., & Evangelou, D. (2015). Engineering curriculum in the preschool classroom: The teacher's experience. European Early Childhood Education Research Journal, 23, 112–118. Bakirci, H., & Karisan, D. (2018). Investigating the preservice primary school, mathematics and science teachers' STEM awareness. Journal of Education and Training Studies, 6(1), 32-42. Bakırcı, H., & Kutlu, E. (2018). Fen bilimleri öğretmenlerinin FeTeMM yaklaşımı hakkındaki görüşlerinin belirlenmesi. Türk Bilgisayar ve Matematik Eğitimi Dergisi, 9(2), 367-389. Bartholomew, S. R., & Strimel, G. J. (2017). Factors influencing student success on open-ended design problems. International Journal of Technology and Design Education, 28(3), 753–770. Bell, D. (2016). The reality of STEM education, design and technology teachers’ perceptions: A phenomenographic study. International Journal of Technology and Design Education, 26(1), 61–79. Bell, P., Lewenstein, B., Shouse, A., & Feder, M. (2009). Learning science in informal environments: People, places, and pursuits. Washington, DC: National Academies Press. Berry, A, McLaughlin, P., & Cooper, G. (2019). Building STEM self-perception and capacity in pre-service science teachers through a school-university mentor program in Tasos Barkatsas. Nicky Carr and Grant Cooper (eds.), STEM Education: An Emerging Field of Inquiry. (pp. 190-207). Koninklijke Brill NV, Leiden, Netherlands. Brown, R., Brown, J., Reardon, K., & Merrill, C. (2011). Understanding STEM: Current perceptions. Technology and Engineering Teacher, 70(6), 5–9. Butz, A., Branchaw, J., Pfund, C., Byars-Winston, A., & Leverett, P. (2018). Promoting STEM trainee research self-efficacy: A mentor training intervention. Understanding Interventions Journal, 9(1). Capraro, R. M., Capraro, M. M., & Morgan, J. (2013). Project-based learning: An integrated science, technology, engineering, and mathematics (STEM) approach (2nd ed.). Rotterdam: Sense. Capraro, R. M., & Corlu, M. S. (2013). Changing views on assessment for STEM projectbased learning. In R. M. Capraro, M. M. Capraro & J. J. Morgan (Eds.), STEM projectbased learning an integrated science, technology, engineering, and mathematics (STEM) approach (pp. 109–118). Boston, MA: Sense Publishers. Carter, L. (2015). The road less travelled: Globalisation, neoliberalism and science education. In J. Zajda (Ed.), The international handbook globalisation and education policy research (pp. 839–850). Dordrecht, The Netherlands: Springer. Chalmers, C., Carter, M., Cooper, T., & Nason, R. (2017). Implementing “big ideas” to advance the teaching and learning of science, technology, engineering, and mathematics (STEM). International Journal of Science and Mathematics Education, 15(1), 25-43. Charlton, A. (2017). Design Thinking and 21st century skills to create a customised test tube rack. A community engagement Project. ResearchGate. Corlu, M. S. (2013). Insights into STEM education praxis: An assessment scheme for course syllabi. Educational Sciences: Theory & Practice, 13, 2477–2485. Crismond, D. P., & Adams, R. S. ( 2012). The informed design teaching and learning matrix. Journal of Engineering Education, 101(4), 738–797. Çorlu, M. S., & Çallı, E. (2017). STEM kuram ve uygulamalarıyla fen, teknoloji, mühendislik ve matematik eğitimi. İstanbul: Pusula Dani, D., Hartman, S. L., & Helfrich, S. (2018). Learning to teach science: Elementary teacher candidates facilitate informal STEM events. The New Educator, 14(4), 363–380. Dare, E., Ellis, J., & Roehrig, G. (2018). Understanding science teachers’ implementations of integrated STEM curricular units through a phenomenological multiple case study. International Journal of STEM Education, 5(4), 1-19. deChambeau, A., & Ramlo, S. (2017). STEM high school teachers’ views of implementing PBL: An investigation using anecdote circles. Interdisciplinary Journal of Problem-Based Learning, 11(1), 7. doi.org/10.7771/1541-5015.1566 DeCoito, I., & Myszkal, P. (2018). Connecting science instruction and teachers’ self-efficacy and beliefs in STEM education. Journal of Science Teacher Education, 29(6), 485-503. DeFreitas, E., Lupinacci, J., & Pais, A. (2017). Science and technology studies  educational studies: Critical and creative perspectives on the future of STEM education. Educational Research, 53(6), 551–559. Ejiwale, J. (2013). Barriers to successful implementation of STEM education. Journal of Education and Learning, 7(2), 63-74. English, L. (2016). STEM education K-12: Perspectives on integration. International Journal of STEM Education, 3(3), 1–8. English, L. D. (2017). Advancing elementary and middle school STEM education. International Journal of Science and Mathematics Education, 15(1), 5-24. English, L. D., Arleback, J. B., & Mousoulides, N. (2016). Reflections on progress in mathematical modelling research. In A. Gutierrez, G. Leder & P. Boero (Eds.), The second handbook of research on the psychology of mathematics education (pp. 383–413). Rotterdam, The Netherlands: Sense Publishers. English, L. D., & King, D. T. (2015). STEM learning through engineering design: Fourth-grade students’ investigations in aerospace. International Journal of STEM Education, 2(14), 1-18. English, L. D., King, D., & Smeed, J. (2017). Advancing integrated STEM learning through engineering design: Sixth-grade students’ design and construction of earthquake resistant buildings. The Journal of Educational Research, 110(3), 255–271. Erdogan, I., & Ciftci, A. (2017). Investigating the views of pre-service science teachers on STEM education practices. International Journal of Environmental and Science Education, 12(5), 1055-1065. Eroğlu, S., & Bektaş, O. (2016). STEM eğitimi almış fen bilimleri öğretmenlerinin STEM temelli ders etkinlikleri hakkındaki görüşleri. Eğitimde Nitel Araştırmalar Dergisi, 4(3), 43-67. Estapa, A. T., & Tank, K. M. (2017). Supporting integrated STEM in the elementary classroom: A professional development approach centered on an engineering design challenge. International Journal of STEM education, 4(6), 1–16. Faber, M., Unfried, A., Wiebe, E. N., Corn, J. Townsend, L. W., & Collins, T. L. (2013, June). Student attitudes toward STEM: The development of upper elementary school and middle/high school student surveys. 120th ASSE Annual Conference & Exposition. Atalanta. Fallik, O., Rosenfeld, S., & Eylon, B. S. (2013). School and out-of-school science: A model for bridging the gap. Studies in Science Education, 49, 69–91. Fan, S. C., & Yu, K. C. (2016). Core value and implementation of the science, technology, engineering, and mathematics curriculum in technology education. Journal of Research in Education Sciences, 61(2), 153–183. Fan, S. C., & Yu, K. C. (2017). How an integrative STEM curriculum can benefit students in engineering design practices. International Journal of Technology and Design Education, 27(1), 107–129. Fan, S. C., Yu, K. C., & Lou, S. J. (2017). Why do students present different design objectives in engineering design projects? International Journal of Technology and Design Education. 28(4), 1039-1060. French, D. A., & Burrows, A. C. (2018). Evidence of science and engineering practices in preservice secondary science teachers’ instructional planning. Journal of Science Education and Technology, 27(6), 536–549. Friday Institute for Educational Innovation (2012). Middle/high school student attitudes toward STEM survey. Raleigh, NC: Author. Guzey S. S., Harwell, M., & Moore, T. (2014). Development of an instrument to measure students’ attitudes toward STEM. School Science and Mathematics, 114(6), 271–279. Guzey, S. S., Harwell, M., Moreno, M., Peralta, Y., & Moore, T. (2017). The impact of design-based STEM integration curricula on student achievement in science, engineering, and mathematics. Journal of Science Education and Technology, 26(2), 207–222. Günbatar, M. S., & Bakırcı, H. (2019). STEM teaching intention and computational thinking skills of pre-service teachers. Education and Information Technologies, 24(2) 1-15. Han, S., Yalvac, B., Capraro, M. M., & Capraro, R. M. (2015). In-service teachers' implementation and understanding of STEM project based learning. Eurasia Journal of Mathematics Science and Technology Education, 11(1), 63–76. Honey, M., Pearson, G., & Schweingruber, A. (2014). STEM integration in K-12 education: Status, prospects, and an agenda for research. Washington: National Academies Press. Hora, M. T., & Oleson, A. K. (2017). Examining study habits in undergraduate STEM courses from a situative perspective. International Journal of STEM Education, 4(1), 1–19. Jaipal-Jamani, K., & Angeli, C. (2017). Effect of robotics on elementary preservice teachers’ self-efficacy, science learning, and computational thinking. Journal of Science Education and Technology, 26, 175–192. Karışan, D., & Bakırcı, H. (2018). Öğretmen adaylarının FeTeMM öğretim yönelimlerinin anabilim dalına ve sınıf düzeyine göre incelenmesi. Adıyaman Üniversitesi Eğitim Bilimleri Dergisi, 8(2), 152-175. Kennedy, T., & Odell, M. (2014). Engaging students in STEM education. Science Education International, 25(3), 246–258. Kier, M., Blanchard, M., Osborne, J., & Albert, J. (2014). The development of the STEM Career Interest Survey (STEM-CIS). Research in Science Education, 44, 461–481. Kim, D., & Bolger, M. (2017). Analysis of Korean elementary pre-service teachers’ changing attitudes about integrated STEAM pedagogy through developing lesson plans. International Journal of Science and Mathematics Education, 15, 587-605. Kim, E., Oliver, J. S., & Kim, Y. A. (2018). Engineering design and the development of knowledge for teaching among preservice science teachers. School Science and Mathematics, 119, 24–34. King, N. S. (2017). When teachers get it right: Voices of black girls informal STEM learning experiences. Journal of Multicultural Affairs, 2(1), 5. 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. Lachapelle C. P., & Cunningham C. M. (2014). Engineering in elementary schools. In: Purzer S, Strobel J, Cardella M (eds.) Engineering in pre-college settings: Synthesizing research, policy, and practices (pp. 61–88). Purdue University Press, West Lafayette. Lee, M. H., Hsu, C. Y., & Chang, C. Y. (2019). Identifying Taiwanese teachers’ perceived self-efficacy for science, technology, engineering, and mathematics (STEM) knowledge. The Asia-Pacific Education Researcher, 28(1),15–23. McGee, E., Thakore, B. K., & LaBlance, S. S. (2016). The burden of being model: Racialized experiences among Asian STEM students. Journal of Diversity in Higher Education, 10(3), 1-18. Martin, B., & Reinking, A. (2018). Key ideas to consider when implementing STEM. The Journal of the Illinois Council of Teachers of Mathematics, 64(1), 1-7. Mentzer, G. A., Czerniak, C. M., & Duckett, T. R. (2019). Comparison of two alternative approaches to quality STEM teacher preparation: Fast-track licensure and embedded residency programs. School Science and Mathematics, 119, 35–48. Miles, M. B., & Huberman, A. M. (1994). Qualitative data analysis: An expanded sourcebook. (2rd edition). Sage. Milfort, M. (2012). An examination of the information technology job market Credentials that work. Washington, DC: Jobs for the Future. Moore, T. J., Stohlmann, M. S., Wang, H., Tank, K. M., Glancy, A. W., & Roehrig, G. H. (2014). Implementation and integration of engineering in K-12 STEM education. In S. Purzer, J. Strobel, & M. Cardella (Eds.), Engineering in pre-college settings: Research into practice (pp. 35–60). West Lafayette, IN: Purdue University Press. National Academy of Engineering and National Research Council [NAE&NRC]. (2009). Engineering in K-12 education: Understanding the status and improving the prospects. Washington: National Academies Press. National Research Council [NRC]. (2012). A Framework for K-12 science education: Practices, crosscutting concepts, and core ideas. Washington DC: The National Academic Press. National Research Council [NRC]. (2014). STEM learning is everywhere: Summary of a convocation on building learning systems. Washington, DC: The National Academies Press. National Science and Technology Council [NSTC]. (2013). National Strategy for Civil Earth Observations. Washington, DC: Executive Office of the President. NGSS Lead States. (2013). Next Generation Science Standards: For states, by states. Washington, DC: The National Academies Press. Novak, E., & Wisdom, S. (2018). Effects of 3d printing project-based learning on preservice elementary teachers’ science attitudes, science content knowledge, and anxiety about teaching science. Journal of Science Education and Technology, 27(5), 412-432. Park, D. Y., Park, M. H., & Bates, A. B. (2016). Exploring young children’s understanding about the concept of volume through engineering design in a STEM activity: A case study. International Journal of Science and Mathematics Education, 16, 275-294. Peters-Burton, E., Lynch, S., Behrend, T., & Means, B. (2014). Inclusive STEM high schools: 10 critical components. Theory Into Practice, 53, 64–71. Price, C. A., Kares, F. K., Segovia, G., & Lloyd, A. B. (2019). Staff Matter: Gender differences in STEM career interest development in adolescent youth. Applied Developmental Science, 23(3), 239-254. Purzer, S., Goldstein, M., Adams, R., Xie, C., & Nourian, S. (2015). An exploratory study of informed engineering design behaviors associated with scientific explanations. International Journal of STEM Education, 2(9), 1–12. Retna, K. S. (2016). Thinking about ‘Design Thinking’: A study of teacher experiences. Asia Pacific Journal of Education, 36(1), 5–19. Ring, E. A., Dare, E. A., Crotty, E. A., & Roehrig, G. H. (2017). Evolution of teacher conceptions of STEM education throughout an intensive professional development experience. Journal of Science Teacher Education, 28(5) 444-467. Roehrig, G. H., Moore, T. J., Wang, H. H., & Park, M. S. (2012). Is adding the E enough? Investigating the impact of K-12 engineering standards on the implementation of STEM integration. School Science and Mathematics, 112(1), 31–44. Schnittka, C. G., & Bell, R. L. (2011). Engineering design and conceptual change in science: Addressing thermal energy and heat transfer in eighth grade. International Journal of Science Education, 33, 1861–1887. Shahali, E. H. M., Halim, L., Rasul, M. S., Osman, K., & Zulkifeli, M. A. (2017). STEM learning through engineering design: Impact on middle secondary students’ interest towards STEM. EURASIA Journal of Mathematics, Science and Technology Education, 13(5), 1189-1211. Shernoff, D. J., Sinha, S., Bressler, D. M., & Ginsburg, L. (2017). Assessing teacher education and professional development needs for the implementation of integrated approaches to STEM education. International Journal of STEM Education, 4(1), 13. Sibuma, B., Wunnava, S., John, M., Anggoro, F., & Dubosarsky, M. (2018). The impact of an integrated Pre-K STEM Curriculum on teachers' engineering content knowledge, self-efficacy, and teaching practices. In: 2018 IEEE Integrated STEM Education Conference (ISEC) (pp. 224–227). Stohlmann, M., Moore, T., & Roehrig, G. (2012). Considerations for teaching integrated STEM education. Journal of Pre-College Engineering Education Research, 2(1), 28–34. Şimşek, H., & Yıldırım, A. (2011). Sosyal bilimlerde nitel araştırma yöntemleri. Ankara: Seçkin Yayınevi. Thomson, M. M., DiFrancesca, D., Carrier, S., Lee, C., & Walkowiak, T. (2018). Changes in teaching efficacy beliefs among elementary preservice teachers from a STEM-focused program: Case study analysis. Journal of Interdisciplinary Teacher Leadership, 2(1), 29-43. Walker, W. S., Moore, T. J., Guzey, S. S., & Sorge, B. H. (2018). Frameworks to develop integrated STEM curricula. K-12 STEM Education, 4(2), 331–339. 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, 1(2), 1–13. Wendell, B., & Rogers, C. (2013). Engineering design-based science, science content performance, and science attitudes in elementary school. Journal of Engineering Education, 102(4), 513–540. Williams, C. T., Walter, E. M., Henderson, C., & Beach, A. L. (2015). Describing undergraduate STEM teaching practices: A comparison of instructor self‐report instruments. International Journal of STEM Education, 2(1), 1–14. Yang, E., Anderson, K. L., & Burke, B. (2014). The impact of service-learning on teacher candidates’ self-efficacy in teaching STEM content to diverse learners. International Journal of Research on Service Learning in Teacher Education, 2, 1-46. Zhou, N., Pereira, N. L., George, T. T., Alperovich, J., Booth, J. Chandrasegaran, S., & vd. (2017). The Influence of Toy Design Activitie son Middle School Students’ Understanding of the Engineering Design Processes. Journal of Science Education and Technology, 26, 481–493.

Tasarım Temelli Öğrenme Uygulamalarının Fen Bilimleri Öğretmen Adaylarının STEM Anlayışlarını Geliştirmeye Etkisi

Year 2020, , 231 - 265, 25.12.2020
https://doi.org/10.33711/yyuefd.691585

Abstract

Bu araştırmanın amacı, tasarım temelli öğrenme uygulamalarının fen bilimleri öğretmen adaylarının STEM anlayışlarını geliştirmeye etkisini incelemektir. Araştırma, tek grup ön test-son test ve izleme testi deneysel araştırma deseninden oluşmaktadır. Araştırmanın örneklemini, 2017-2018 eğitim-öğretim yılı bahar döneminde Kafkas Üniversitesi Dede Korkut Eğitim Fakültesi Fen Bilgisi Öğretmenliği Programı 3. sınıfta öğrenim gören 36 öğretmen adayı oluşturmaktadır. Araştırmanın deneysel uygulaması, fen bilgisi öğretmen adaylarının lisans programı “Özel Öğretim Yöntemleri-I” dersinde gruplar halinde tasarım problemlerinin çözümü üzerinde çalışmalarını içermektedir. Araştırmanın verileri “STEM Yetkinlik Algısı Ölçeği”, “STEM Alanları Bilgisi Değerlendirme Formu” ve “Görüşme Formu” ile toplanmıştır. Araştırmanın nicel verileri ön test, son test ve izleme testi olarak tekrarlı ölçümler yoluyla, nitel veriler ise sadece deneysel uygulama sonrasında elde edilmiştir. Araştırmanın nicel verileri ilişkili örneklemler için tek faktörlü ANOVA testi kullanılarak analiz edilmiştir. Nitel veriler ise içerik analizi yoluyla çözümlenmiştir. Araştırmanın nicel verilerinden elde edilen bulgular, tasarım temelli öğrenme uygulamalarının fen bilgisi öğretmen adaylarının STEM yetkinliklerini ve STEM alanları bilgi düzeylerini geliştirmede önemli etkiye sahip olduğunu göstermiştir. Nitel verilerden elde edilen bulgular ise tasarım temelli öğrenmenin öğretmen adaylarının STEM eğitimi, STEM kariyer beklentileri, beceri gelişimi ve öğrenci öğrenmesinde nasıl kullanılması gerektiğine ilişkin anlayışlarını geliştirmeye önemli etkileri olduğunu ortaya koymuştur.

References

  • Adedokun, O. A., Bessenbacher, A. B., Parker, L. C., Kirkham, L. L., & Burgess, W. D. (2013). Research skills and STEM undergraduate research students' aspirations for research careers: Mediating effects of research self‐efficacy. Journal of Research in Science Teaching, 50, 940–951. Akgündüz, D., Aydeniz, M., Çakmakçı, G., Çavaş, B., Çorlu, M. S., Öner, T., & vd. (2015). STEM eğitimi Türkiye raporu: Günün modası mı yoksa gereksinim mi? [A report on STEM Education in Turkey: A provisional agenda or a necessity?] [White Paper]. İstanbul, Turkey: Aydın Üniversitesi. Retrieved from http://www.aydin.edu.tr/belgeler/IAUSTEM-Egitimi-Turkiye-Raporu2015.pdf Allendoerfer, C., Wilson, D., Kim, M. J., & Burpee, E. (2014). Mapping beliefs about teaching to patterns of instruction within science, technology, engineering, and mathematics. Teaching in Higher Education, 19(7), 758–771. 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. Arslanhan, H. (2019). Tasarım temelli öğrenme uygulamalarının fen bilimleri öğretmen adaylarının STEM anlayışlarını geliştirmeye etkisi. (Yayımlanmamış yüksek lisans tezi). Kafkas Üniversitesi, Fen Bilimleri Enstitüsü, Kars. Avery, Z. K., & Reeve, E. M. (2013). Developing effective STEM professional development programs. Journal of Technology Education, 25(1), 55–69. Asunda, P. A., & Hill, R. B. (2007). Critical features of engineering design in technology education. Journal of Industrial Teacher Education, 44(1), 25–48. Awad, N., & Barak, M. (2018). Pre-service science teachers learn a science, technology, engineering and mathematics (STEM)-oriented program: The case of sound, waves and commication systems. EURASIA Jornal of Mathematics, Science and Technology Education, 14(4), 1431-1451. Ayaz, E. & Sarikaya, R. (2019). The effect of engineering design-based science teaching on the perceptions of classroom teacher candidates towards STEM disciplines. International Journal of Progressive Education, 15(3), 13-27. Aydın-Günbatar, S. A., Tarkın-Çelikkıran, A., Kutucu, E. S., & Ekiz-Kıran, B. (2018). The influence of a design-based elective stem course on pre-service chemistry teachers’ content knowledge, STEM conceptions, and engineering views. Chemistry Education Research and Practice, 19(3), 954-972. doi: 10.1039/C8RP00128. Bagiati, A., & Evangelou, D. (2015). Engineering curriculum in the preschool classroom: The teacher's experience. European Early Childhood Education Research Journal, 23, 112–118. Bakirci, H., & Karisan, D. (2018). Investigating the preservice primary school, mathematics and science teachers' STEM awareness. Journal of Education and Training Studies, 6(1), 32-42. Bakırcı, H., & Kutlu, E. (2018). Fen bilimleri öğretmenlerinin FeTeMM yaklaşımı hakkındaki görüşlerinin belirlenmesi. Türk Bilgisayar ve Matematik Eğitimi Dergisi, 9(2), 367-389. Bartholomew, S. R., & Strimel, G. J. (2017). Factors influencing student success on open-ended design problems. International Journal of Technology and Design Education, 28(3), 753–770. Bell, D. (2016). The reality of STEM education, design and technology teachers’ perceptions: A phenomenographic study. International Journal of Technology and Design Education, 26(1), 61–79. Bell, P., Lewenstein, B., Shouse, A., & Feder, M. (2009). Learning science in informal environments: People, places, and pursuits. Washington, DC: National Academies Press. Berry, A, McLaughlin, P., & Cooper, G. (2019). Building STEM self-perception and capacity in pre-service science teachers through a school-university mentor program in Tasos Barkatsas. Nicky Carr and Grant Cooper (eds.), STEM Education: An Emerging Field of Inquiry. (pp. 190-207). Koninklijke Brill NV, Leiden, Netherlands. Brown, R., Brown, J., Reardon, K., & Merrill, C. (2011). Understanding STEM: Current perceptions. Technology and Engineering Teacher, 70(6), 5–9. Butz, A., Branchaw, J., Pfund, C., Byars-Winston, A., & Leverett, P. (2018). Promoting STEM trainee research self-efficacy: A mentor training intervention. Understanding Interventions Journal, 9(1). Capraro, R. M., Capraro, M. M., & Morgan, J. (2013). Project-based learning: An integrated science, technology, engineering, and mathematics (STEM) approach (2nd ed.). Rotterdam: Sense. Capraro, R. M., & Corlu, M. S. (2013). Changing views on assessment for STEM projectbased learning. In R. M. Capraro, M. M. Capraro & J. J. Morgan (Eds.), STEM projectbased learning an integrated science, technology, engineering, and mathematics (STEM) approach (pp. 109–118). Boston, MA: Sense Publishers. Carter, L. (2015). The road less travelled: Globalisation, neoliberalism and science education. In J. Zajda (Ed.), The international handbook globalisation and education policy research (pp. 839–850). Dordrecht, The Netherlands: Springer. Chalmers, C., Carter, M., Cooper, T., & Nason, R. (2017). Implementing “big ideas” to advance the teaching and learning of science, technology, engineering, and mathematics (STEM). International Journal of Science and Mathematics Education, 15(1), 25-43. Charlton, A. (2017). Design Thinking and 21st century skills to create a customised test tube rack. A community engagement Project. ResearchGate. Corlu, M. S. (2013). Insights into STEM education praxis: An assessment scheme for course syllabi. Educational Sciences: Theory & Practice, 13, 2477–2485. Crismond, D. P., & Adams, R. S. ( 2012). The informed design teaching and learning matrix. Journal of Engineering Education, 101(4), 738–797. Çorlu, M. S., & Çallı, E. (2017). STEM kuram ve uygulamalarıyla fen, teknoloji, mühendislik ve matematik eğitimi. İstanbul: Pusula Dani, D., Hartman, S. L., & Helfrich, S. (2018). Learning to teach science: Elementary teacher candidates facilitate informal STEM events. The New Educator, 14(4), 363–380. Dare, E., Ellis, J., & Roehrig, G. (2018). Understanding science teachers’ implementations of integrated STEM curricular units through a phenomenological multiple case study. International Journal of STEM Education, 5(4), 1-19. deChambeau, A., & Ramlo, S. (2017). STEM high school teachers’ views of implementing PBL: An investigation using anecdote circles. Interdisciplinary Journal of Problem-Based Learning, 11(1), 7. doi.org/10.7771/1541-5015.1566 DeCoito, I., & Myszkal, P. (2018). Connecting science instruction and teachers’ self-efficacy and beliefs in STEM education. Journal of Science Teacher Education, 29(6), 485-503. DeFreitas, E., Lupinacci, J., & Pais, A. (2017). Science and technology studies  educational studies: Critical and creative perspectives on the future of STEM education. Educational Research, 53(6), 551–559. Ejiwale, J. (2013). Barriers to successful implementation of STEM education. Journal of Education and Learning, 7(2), 63-74. English, L. (2016). STEM education K-12: Perspectives on integration. International Journal of STEM Education, 3(3), 1–8. English, L. D. (2017). Advancing elementary and middle school STEM education. International Journal of Science and Mathematics Education, 15(1), 5-24. English, L. D., Arleback, J. B., & Mousoulides, N. (2016). Reflections on progress in mathematical modelling research. In A. Gutierrez, G. Leder & P. Boero (Eds.), The second handbook of research on the psychology of mathematics education (pp. 383–413). Rotterdam, The Netherlands: Sense Publishers. English, L. D., & King, D. T. (2015). STEM learning through engineering design: Fourth-grade students’ investigations in aerospace. International Journal of STEM Education, 2(14), 1-18. English, L. D., King, D., & Smeed, J. (2017). Advancing integrated STEM learning through engineering design: Sixth-grade students’ design and construction of earthquake resistant buildings. The Journal of Educational Research, 110(3), 255–271. Erdogan, I., & Ciftci, A. (2017). Investigating the views of pre-service science teachers on STEM education practices. International Journal of Environmental and Science Education, 12(5), 1055-1065. Eroğlu, S., & Bektaş, O. (2016). STEM eğitimi almış fen bilimleri öğretmenlerinin STEM temelli ders etkinlikleri hakkındaki görüşleri. Eğitimde Nitel Araştırmalar Dergisi, 4(3), 43-67. Estapa, A. T., & Tank, K. M. (2017). Supporting integrated STEM in the elementary classroom: A professional development approach centered on an engineering design challenge. International Journal of STEM education, 4(6), 1–16. Faber, M., Unfried, A., Wiebe, E. N., Corn, J. Townsend, L. W., & Collins, T. L. (2013, June). Student attitudes toward STEM: The development of upper elementary school and middle/high school student surveys. 120th ASSE Annual Conference & Exposition. Atalanta. Fallik, O., Rosenfeld, S., & Eylon, B. S. (2013). School and out-of-school science: A model for bridging the gap. Studies in Science Education, 49, 69–91. Fan, S. C., & Yu, K. C. (2016). Core value and implementation of the science, technology, engineering, and mathematics curriculum in technology education. Journal of Research in Education Sciences, 61(2), 153–183. Fan, S. C., & Yu, K. C. (2017). How an integrative STEM curriculum can benefit students in engineering design practices. International Journal of Technology and Design Education, 27(1), 107–129. Fan, S. C., Yu, K. C., & Lou, S. J. (2017). Why do students present different design objectives in engineering design projects? International Journal of Technology and Design Education. 28(4), 1039-1060. French, D. A., & Burrows, A. C. (2018). Evidence of science and engineering practices in preservice secondary science teachers’ instructional planning. Journal of Science Education and Technology, 27(6), 536–549. Friday Institute for Educational Innovation (2012). Middle/high school student attitudes toward STEM survey. Raleigh, NC: Author. Guzey S. S., Harwell, M., & Moore, T. (2014). Development of an instrument to measure students’ attitudes toward STEM. School Science and Mathematics, 114(6), 271–279. Guzey, S. S., Harwell, M., Moreno, M., Peralta, Y., & Moore, T. (2017). The impact of design-based STEM integration curricula on student achievement in science, engineering, and mathematics. Journal of Science Education and Technology, 26(2), 207–222. Günbatar, M. S., & Bakırcı, H. (2019). STEM teaching intention and computational thinking skills of pre-service teachers. Education and Information Technologies, 24(2) 1-15. Han, S., Yalvac, B., Capraro, M. M., & Capraro, R. M. (2015). In-service teachers' implementation and understanding of STEM project based learning. Eurasia Journal of Mathematics Science and Technology Education, 11(1), 63–76. Honey, M., Pearson, G., & Schweingruber, A. (2014). STEM integration in K-12 education: Status, prospects, and an agenda for research. Washington: National Academies Press. Hora, M. T., & Oleson, A. K. (2017). Examining study habits in undergraduate STEM courses from a situative perspective. International Journal of STEM Education, 4(1), 1–19. Jaipal-Jamani, K., & Angeli, C. (2017). Effect of robotics on elementary preservice teachers’ self-efficacy, science learning, and computational thinking. Journal of Science Education and Technology, 26, 175–192. Karışan, D., & Bakırcı, H. (2018). Öğretmen adaylarının FeTeMM öğretim yönelimlerinin anabilim dalına ve sınıf düzeyine göre incelenmesi. Adıyaman Üniversitesi Eğitim Bilimleri Dergisi, 8(2), 152-175. Kennedy, T., & Odell, M. (2014). Engaging students in STEM education. Science Education International, 25(3), 246–258. Kier, M., Blanchard, M., Osborne, J., & Albert, J. (2014). The development of the STEM Career Interest Survey (STEM-CIS). Research in Science Education, 44, 461–481. Kim, D., & Bolger, M. (2017). Analysis of Korean elementary pre-service teachers’ changing attitudes about integrated STEAM pedagogy through developing lesson plans. International Journal of Science and Mathematics Education, 15, 587-605. Kim, E., Oliver, J. S., & Kim, Y. A. (2018). Engineering design and the development of knowledge for teaching among preservice science teachers. School Science and Mathematics, 119, 24–34. King, N. S. (2017). When teachers get it right: Voices of black girls informal STEM learning experiences. Journal of Multicultural Affairs, 2(1), 5. 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. Lachapelle C. P., & Cunningham C. M. (2014). Engineering in elementary schools. In: Purzer S, Strobel J, Cardella M (eds.) Engineering in pre-college settings: Synthesizing research, policy, and practices (pp. 61–88). Purdue University Press, West Lafayette. Lee, M. H., Hsu, C. Y., & Chang, C. Y. (2019). Identifying Taiwanese teachers’ perceived self-efficacy for science, technology, engineering, and mathematics (STEM) knowledge. The Asia-Pacific Education Researcher, 28(1),15–23. McGee, E., Thakore, B. K., & LaBlance, S. S. (2016). The burden of being model: Racialized experiences among Asian STEM students. Journal of Diversity in Higher Education, 10(3), 1-18. Martin, B., & Reinking, A. (2018). Key ideas to consider when implementing STEM. The Journal of the Illinois Council of Teachers of Mathematics, 64(1), 1-7. Mentzer, G. A., Czerniak, C. M., & Duckett, T. R. (2019). Comparison of two alternative approaches to quality STEM teacher preparation: Fast-track licensure and embedded residency programs. School Science and Mathematics, 119, 35–48. Miles, M. B., & Huberman, A. M. (1994). Qualitative data analysis: An expanded sourcebook. (2rd edition). Sage. Milfort, M. (2012). An examination of the information technology job market Credentials that work. Washington, DC: Jobs for the Future. Moore, T. J., Stohlmann, M. S., Wang, H., Tank, K. M., Glancy, A. W., & Roehrig, G. H. (2014). Implementation and integration of engineering in K-12 STEM education. In S. Purzer, J. Strobel, & M. Cardella (Eds.), Engineering in pre-college settings: Research into practice (pp. 35–60). West Lafayette, IN: Purdue University Press. National Academy of Engineering and National Research Council [NAE&NRC]. (2009). Engineering in K-12 education: Understanding the status and improving the prospects. Washington: National Academies Press. National Research Council [NRC]. (2012). A Framework for K-12 science education: Practices, crosscutting concepts, and core ideas. Washington DC: The National Academic Press. National Research Council [NRC]. (2014). STEM learning is everywhere: Summary of a convocation on building learning systems. Washington, DC: The National Academies Press. National Science and Technology Council [NSTC]. (2013). National Strategy for Civil Earth Observations. Washington, DC: Executive Office of the President. NGSS Lead States. (2013). Next Generation Science Standards: For states, by states. Washington, DC: The National Academies Press. Novak, E., & Wisdom, S. (2018). Effects of 3d printing project-based learning on preservice elementary teachers’ science attitudes, science content knowledge, and anxiety about teaching science. Journal of Science Education and Technology, 27(5), 412-432. Park, D. Y., Park, M. H., & Bates, A. B. (2016). Exploring young children’s understanding about the concept of volume through engineering design in a STEM activity: A case study. International Journal of Science and Mathematics Education, 16, 275-294. Peters-Burton, E., Lynch, S., Behrend, T., & Means, B. (2014). Inclusive STEM high schools: 10 critical components. Theory Into Practice, 53, 64–71. Price, C. A., Kares, F. K., Segovia, G., & Lloyd, A. B. (2019). Staff Matter: Gender differences in STEM career interest development in adolescent youth. Applied Developmental Science, 23(3), 239-254. Purzer, S., Goldstein, M., Adams, R., Xie, C., & Nourian, S. (2015). An exploratory study of informed engineering design behaviors associated with scientific explanations. International Journal of STEM Education, 2(9), 1–12. Retna, K. S. (2016). Thinking about ‘Design Thinking’: A study of teacher experiences. Asia Pacific Journal of Education, 36(1), 5–19. Ring, E. A., Dare, E. A., Crotty, E. A., & Roehrig, G. H. (2017). Evolution of teacher conceptions of STEM education throughout an intensive professional development experience. Journal of Science Teacher Education, 28(5) 444-467. Roehrig, G. H., Moore, T. J., Wang, H. H., & Park, M. S. (2012). Is adding the E enough? Investigating the impact of K-12 engineering standards on the implementation of STEM integration. School Science and Mathematics, 112(1), 31–44. Schnittka, C. G., & Bell, R. L. (2011). Engineering design and conceptual change in science: Addressing thermal energy and heat transfer in eighth grade. International Journal of Science Education, 33, 1861–1887. Shahali, E. H. M., Halim, L., Rasul, M. S., Osman, K., & Zulkifeli, M. A. (2017). STEM learning through engineering design: Impact on middle secondary students’ interest towards STEM. EURASIA Journal of Mathematics, Science and Technology Education, 13(5), 1189-1211. Shernoff, D. J., Sinha, S., Bressler, D. M., & Ginsburg, L. (2017). Assessing teacher education and professional development needs for the implementation of integrated approaches to STEM education. International Journal of STEM Education, 4(1), 13. Sibuma, B., Wunnava, S., John, M., Anggoro, F., & Dubosarsky, M. (2018). The impact of an integrated Pre-K STEM Curriculum on teachers' engineering content knowledge, self-efficacy, and teaching practices. In: 2018 IEEE Integrated STEM Education Conference (ISEC) (pp. 224–227). Stohlmann, M., Moore, T., & Roehrig, G. (2012). Considerations for teaching integrated STEM education. Journal of Pre-College Engineering Education Research, 2(1), 28–34. Şimşek, H., & Yıldırım, A. (2011). Sosyal bilimlerde nitel araştırma yöntemleri. Ankara: Seçkin Yayınevi. Thomson, M. M., DiFrancesca, D., Carrier, S., Lee, C., & Walkowiak, T. (2018). Changes in teaching efficacy beliefs among elementary preservice teachers from a STEM-focused program: Case study analysis. Journal of Interdisciplinary Teacher Leadership, 2(1), 29-43. Walker, W. S., Moore, T. J., Guzey, S. S., & Sorge, B. H. (2018). Frameworks to develop integrated STEM curricula. K-12 STEM Education, 4(2), 331–339. 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, 1(2), 1–13. Wendell, B., & Rogers, C. (2013). Engineering design-based science, science content performance, and science attitudes in elementary school. Journal of Engineering Education, 102(4), 513–540. Williams, C. T., Walter, E. M., Henderson, C., & Beach, A. L. (2015). Describing undergraduate STEM teaching practices: A comparison of instructor self‐report instruments. International Journal of STEM Education, 2(1), 1–14. Yang, E., Anderson, K. L., & Burke, B. (2014). The impact of service-learning on teacher candidates’ self-efficacy in teaching STEM content to diverse learners. International Journal of Research on Service Learning in Teacher Education, 2, 1-46. Zhou, N., Pereira, N. L., George, T. T., Alperovich, J., Booth, J. Chandrasegaran, S., & vd. (2017). The Influence of Toy Design Activitie son Middle School Students’ Understanding of the Engineering Design Processes. Journal of Science Education and Technology, 26, 481–493.
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Details

Primary Language Turkish
Journal Section Articles
Authors

Hicran Arslanhan This is me 0000-0002-3824-9579

Tufan İnaltekin This is me 0000-0002-3843-7393

Publication Date December 25, 2020
Published in Issue Year 2020

Cite

APA Arslanhan, H., & İnaltekin, T. (2020). Tasarım Temelli Öğrenme Uygulamalarının Fen Bilimleri Öğretmen Adaylarının STEM Anlayışlarını Geliştirmeye Etkisi. Van Yüzüncü Yıl Üniversitesi Eğitim Fakültesi Dergisi, 17(1), 231-265. https://doi.org/10.33711/yyuefd.691585