___

• Akbaş, A., & Kan, A. (2007). Affective factors that influence chemistry achievement (motivation and anxiety) and the power of these factors to predict chemistry achievement-II. Journal of Turkish Science Educatıon, 4(1), 9–18.
• Alataş, B., & Akın, E. (2004). Veri madenciliğinde yeni yaklaşımlar. Paper presented at the YA-EM'2004 Congress, Adana.
• Altaş, İ. H. (1999). Bulanık mantık: Bulanıklık kavramı (Fuzzy logic: concept of fuzzy logic). Enerji, Elektrik, Elektromekanik-3e, 62, 80–85.
• Altun, M. (2008). Matematik öğretimi (Teaching mathematics). Bursa: Alfa Basım Yayım Dağıtım.
• Aypay, A., Erdoğan, E., & Sözer, M. A. (2007). Variation among schools on classroom practices in science based on TIMSS–1999 in Turkey. Journal of Research in Science Teaching, 44(10), 1417–1435.
• Baloğlu, M. (2001). Matematik korkusunu yenmek (To cope with math anxity). Educational Sciences: Theory & Practice, 1(1), 59–76.
• Bandura, A. (1995). Self-efficacy in changing societies. Cambridge: Cambridge University Press.
• Barkatsas, A, Kasimatis, K., & Gialamas, V. (2009). Learning secondary mathematics with technology: Exploring the complex interrelationship between students’ attitudes, engagement, gender and achievement. Computers and Education, 52, 562–570.
• Basista, B., & Mathews, S. (2002). Integrated science and mathematics professional development programs. School Science and Mathematics, 102(7), 359–370.
• Bassok, M., & Holyoak, K. J. (1989). Interdomain transfer between isomorphic topics in algebra and physics. Learning, Memory, and Cognition, 15(1), 153–166.
• Basson, I. (2002). Physics and mathematics as interrelated fields of thought development using acceleration as an example. International Journal of Mathematical Education in Science and Technology, 33(5), 679–690.
• Bekdemir, M. (2007). The causes of mathematics anxiety in elementary preservice teachers and proposals for decreasing mathematics anxiety. The example of faculty of Erzincan education. Erzincan Eğitim Fakültesi Dergisi, 9(2), 131–144.
• Belbase, S. (2013). Images, anxieties, and attitudes toward mathematics. International Journal of Education in Mathematics, Science and Technology, 1(4), 230-237.
• Berberoğlu, G., & Kalender, İ. (2005). Investigation of student achievement across years, school types and regions: The SSE and PISA analyses. Eğitim Bilimleri ve Uygulama, 4(7), 21–35.
• Berlin, D.F. & White, A.L. (1994). The Berlin-White Integrated Science and Mathematics Model. School Science and Mathematics, 94(1), 2–4.
• Berlin, D. F. (1991). A bibliography of integrated science and mathematics teaching and learning literature. School Science and Mathematics Association Topics for Teacher Series (No. 6). Bowling Green, OH: School Science and Mathematics Association.
• Berry, M., & Linoff, G. (2000). Mastering data mining: The art and science of customer relationship management. New York: John Wiley & Sons.
• Bilgin, İ. (2006). The effects of hands-on activities incorporating a cooperative learning approach on eighth-grade students’ science process skills and attitudes toward science. Journal of Baltic Science Education, 1(9), 27–37.
• Blanchette, I., & Dunbar, K. (2002). Representational change and analogy: How analogical inferences alter target representations. Journal of Experimental Psychology: Learning, Memory, and Cognition, 28, 672–685.
• Brookover, W. B., Thomas, S. & Peterson, A. (1964). Self-concept of ability and school performance. Sociology of Education, 37, 271–278.
• Bursal, M. (2008). Changes in Turkish pre-service elementary teachers’ personal science teaching efficacy beliefs and science anxieties during a science method course. Journal of Turkish Science Education, 5 (1).
• Bursal, M., & Paznokas, L. (2006). Mathematics anxiety and preservice elementary teachers’ confidence to teach mathematics and science. School Science and Mathematics, 106(4), 173–180.
• Byrne, B. M. (1996). Measuring self-concept across the life span. Issues and instrumentation. Washington, DC: American Psychological Association.
• Cahan, D. (2003). From natural philosophy to the sciences: Writing the history of nineteenth- century science. London: University of Chicago Press.
• Caston, M. (1986). Parent and student attitudes toward mathematics as they relate to third grade mathematics achievement. Research report. (Eric Document Reproduction No. ED334078).
• Chien, C., & Chen, L. (2008). Data mining to improve personnel selection and enhance human capital: A case study in high-technology industry. Expert Systems with Applications, 34, 280–290.
• Chui, C., Chen, Y., Kou, I., & Ku, H. C. (2009). An intelligent market segmentation system using k-means and particle swarm optimization. Expert Systems with Applications, 36(1), 4558–4565.
• Davison, D. M., Miller, K. W., & Metheny, D. L. (1995). What does integration of science and mathematics really mean? School Science and Mathematics, 95(5), 226–230.
• Dede, Y., & Yaman, S. (2008). A questionnaire for motivation toward science learning: A validity and reliability study. Necatibey Faculty of Education Electronic Journal of Science and Mathematics Education, 2(1), 19–37.
• Delen, D., Walker, G., & Kadam, A. (2005). Predicting breast cancer survivability: A comparison of three data mining methods. Artificial Intelligence in Medicine, 34, 113–127.
• Demir, İ., & Kılıç, S. (2009). Matematikte başarı üzerine öğrencilerin kendileriyle ilgili görüşleri (Students’ self efficacy about themselves on the math achievement). Paper peresented at the 6th Statistics Congress, Antalya.
• Dewey, J. (1969). Interest and effort in education. New York: Augustus M. Kelley Publishers.
• Dewey, J. (1933). How we think. Boston, MA: Heath and Company.
• Dotterer, A. M., McHale, S. M., & Crouter, A. C. (2009). The development and correlates of academic interests from childhood through adolescence. Journal of Educational Psychology, 101(2), 509–519.
• EARGED. (2005). Öğrenci başarısını belirleme programı (PISA–2003), ulusal ön rapor (Student achievement determining program (PISA-2003), national preliminary report). Ankara: MEB-Eğitimi Araştırma ve Geliştirme Dairesi Başkanlığı.
• EARGED. (2003). TIMSS-R: Third international mathematics and science study-repeat/ üçüncü uluslararası matematik ve fen araştırmasının tekrarı-uluslararası ölçme ve değerlendirme çalışmaları (international measurement and assessment studies). Ankara: MEB Eğitimi Araştırma ve Geliştirme Dairesi (EARGED) Yay. (http://earged.meb.gov.tr)
• Eggen, P., & Kauchak, D. (2001). Educational psychology: Windows on classrooms. New Jersey: Prentice Hall.
• Erten, S. (2008). Interests of 5th through 10th grade students toward human biology. Hacettepe University, Journal of Education, 35, 135–147.
• Friend, H. (1985). The effect of science and mathematics integration on selected seventh- grade students’ attitudes toward and achievement in science. School Science and Mathematics, 85(6), 453–461.
• Gardner, P. L., & Tamir, P. (1989). Interest in biology. Part I: A multidimensional construct. Journal of Research in Science Teaching, 26(5), 409–423.
• Girasoli, A. J., & Hannafin, R. D. (2008). Using asynchronous AV communication tools to increase academic self-efficacy. Computers and Education, 51, 1676–1682.
• Gleick, J. (1987). Chaos: Making a new science. New York: Viking Press.
• Gonzalez, E. J., & Miles, J. A. (Eds.) (2001). TIMSS 1999 user guide for the international database: IEA’s repeat of the third ınternational mathematics and science study at the eighth grade. Lynch School of Education, Boston, MA: International Study Center, Boston College.
• Gömleksiz, M. N. (2003). Validity and reliability of an attitude scale on affective domain in English course. Fırat University Journal of Social Science, 13(1), 215-226.
• Guay, F., Marsh, H. W., & Boivin, M. (2003). Academic self-concept and academic achievement: Developmental perspectives and their causal ordering. Journal of Educational Psychology, 95, 124–136.
• Güleç, S., & Alkış, S. (2003). Relations among primary school students’ course performances. İlköğretim-Online, 2 (2), 19–27.
• Güngör, A., Eryılmaz, A., & Fakıoğlu, T. (2007). The relationship of freshmen’s physics achievement and their related affective characteristics. Journal of Research in Science Teachıng, 44(8), 1036–1056.
• Harper, N. W., & Daane, C. J. (1998). Causes and reduction of math anxiety in preservice elementary teachers. Action in Teacher Education, 19(4), 29–38.
• Hembree, R. (1990). The nature, effects and relief of mathematics anxiety. Journal for Research in Mathematics Education, 21(1), 33–46.
• Hendrickson, A. B. (1997). Predicting student success with the learning and study strategies 14. inventory (LASSI). Unpublished Master’s thesis. Iowa State University, Ames, IA.
• Hizarcı, T., Atılboz, N. G., & Salman, S. (2005). A study on the attitudes of elementary school students from two different socio-economic regions towards living organisms. Journal of Gazi Educational Faculty, 25(2), 55–69.
• House, J. D. (2004). Cognitive-motivational characteristics and science achievement of adolescent students: results from the tımss 1995 and tımss 1999 assesments. International Journal of Instructional Media, 31(4), 411-424.
• House, P. (1990). Science and mathematics: partners then… partners now. School Science and Mathematics Association Topics for Teachers Series, No. 5. Bowling Green, OH: School Science and Mathematics Association.
• İnceoğlu, M. (2004). Tutum algı iletişim (Attitude, perception, communication). Ankara: Elips Kitap Kesit Tanıtım.
• Ireland, J. D. (1987). The effect of reading performance on high school science achievement. Unpublished Master’s thesis, Curtin University of Technology, Perth, Western Australia.
• Kıray, S.A. (2010). İlköğretim ikinci kademede uygulanan fen ve matematik entegrasyonunun etkililiği, Doktora Tezi, Hacettepe Üniversitesi Sosyal Bilimler Enstitüsü, Ankara.
• Kıray, S.A. (2003). İlköğretim 7. sınıflarda fen bilgisi dersinde uygulanan problem çözme stratejisinin öğrencilerin kavramları anlama ve problem çözme performansları üzerine etkisi. Yayımlanmamış Yüksek Lisans Tezi. Konya: Selçuk Üniversitesi, Fen Bilimleri Enstitüsü.
• Kıray, S.A. & Kaptan, F. (2012). The effectiveness of an integrated science and mathematics programme: Science-centred mathematics-assisted integration. Energy Education Science and Technology Part B: Social and Educational Studies, 4(2), 943-956.
• Kıray, S.A. (2012). A new model for the integration of science and mathematics: The balance model. Energy Education Science and Technology Part B: Social and Educational Studies, 4(3), 1181-1196.
• Kurt, K. & Pehlivan, M. (2013). Integrated programs for science and mathematics: review of related literature. International Journal of Education in Mathematics, Science and Technology, 1(2), 116-121.
• Labenne, W. D., & Greene, B. L. (1969). Educational implications of self concept theory. Pacific Palisades, CA: Goodyear Publishing.
• Lederman, N. G., & Niess, M. L. (1998). 5 Apples + 4 oranges=? School Science and Mathematics, 98(6), 281–284.
• Manger, T., & Eikeland, O. J. (1998). The effect of mathematics self-concept on girls’ and boys’ mathematical achievement. School Psychology International, 19(1), 5–18.
• Marsh, H. (1992). Content specificity of relations between academic achievement and academic self concept. Journal of Educational Phychology, 84(1), 34–52.
• Mataka, L.M., Cobern, W.W., Grunert, M., Mutambuki, J., & Akom, G. (2014). The effect of using an explicit general problem solving teaching approach on elementary pre-service teachers’ ability to solve heat transfer problems. International Journal of Education in Mathematics, Science and Technology, 2(3), 164-174.
• MEB (2005). İlköğretim fen ve teknoloji dersi öğretim programı ve kılavuzu (6–8.sınıflar) (Primary science and technology course teaching program and guide). Ankara: MEB yayınevi.
• McBride, J. W., & Silverman, F. L. (1991). Integrating elementary/middle school science and mathematics. School Science and Mathematics, 91(7), 285–292.
• Mehmetlioglu, D. & Ozdem, Y. (2014). Connectivity Theory at work: The referrals between science and mathematics in a science unit. International Journal of Education in Mathematics, Science and Technology, 2(1), 36-48.
• Miller, H. J., & Han, J. (2001). Geographic data mining and knowledge discovery. In H. J. Miller & J. Han (eds), Geographic data mining and knowledge discovery (pp. 3–32). London and New York: Taylor & Francis.
• Mitra, S., Pal, S. K., & Mitra, P. (2002). Data mining in soft computing framework: A survey. IEEE Transactions on Neural Networks, 13(1).
• Oliver, J. S., & Simpson, R. D. (1988). Influences of attitude toward science, achievement, motivation, and science self-concept on achievement in science: A longitudinal study. Science Education, 72, 143–155.
• Papanastasiou, E., & Zembylas, M. (2004). Differential effects of science attitudes and science achievement in Australia, Cyprus, and the USA. International Journal of Science Education, 26, 259–280.
• Perla, R. J. & Carifio, J. (2005). The nature of scientific revolutions from the vantage point of chaos theory. Science & Education, 14, 263–290.
• Polya, G. (1945). How to solve it: A new aspect of mathematical method. New Jersey: Princeton University Pres.
• Serin, O. (2004). Öğretmen adaylarının problem çözme becerisi ve fene yönelik tutum ile başarıları arasındaki ilişki (Relationship between pre-service teachers’ problem solving skills, attitude towards science and achievement). Paper presented at the 13th Educational Sciences Congress, University of İnönü, Malatya. Retrieved May 10, 2010, from http://www.pegema.net/dosya/dokuman/415.pdf
• Shelley, M. & Yildirim, A. (2013). Transfer of learning in mathematics, science, and reading among students in Turkey: A study using 2009 PISA data. International Journal of Education in Mathematics, Science and Technology, 1(2), 83-95.
• Sherman B. F., & Wither, D. P. (2003). Mathematics anxiety and mathematics achievement. Mathematics Education Research Journal, 15(2), 138–150.
• Sloan, T., Daane, C. J., & Giesen, J. (2002). Mathematics anxiety and learning styles: What is the relationship in elementary preservice teachers? School Science and Mathematics, 102(2), 84–87.
• Sloutsky, V. M., Kaminski, J. A., & Heckler, A. F. (2004). Transfer of learning between isomorphic artificial domains: Advantage for the abstract. In Proceedings of the XXVI Annual Conference of the Cognitive Science Society (pp. 1167–1172). Mahwah, NJ: Erlbaum.
• Sloutsky, V. M., Kaminski, J. A., & Heckler, A. F. (2005). The advantage of simple symbols for learning and transfer. Psychonomic Bulletin & Review, 12, 508–513.
• Sousa, D. A. (2006). How the brain learns. Thousand Oaks, CA: Corwin Press.
• Tan, P. N., Steinbach, M., & Kumar, V. (2005). Introduction to data mining. Boston, MA: Addison-Wesley.
• Tang, Z., & MacLennan, J. (2005). Data mining with SQL server. Indianapolis, IN: Wiley Publishing, Inc.
• Taşdemir, M., & Taşdemir, A. (2008). A comparison of Turkish primary school students’ achievement in science and maths subjects. Journal of Qafqaz University, 22, 190–198.
• Tavşancıl, E. (2006). Tutumların ölçülmesi ve spss ile veri analizi (Measurement of attitudes and data analysis with SPSS). Ankara: Nobel Yayın Dağıtım.
• Tschannen-Moran, M. & Mcmaster, P. (2009). Sources of self-efficacy: Four professional development formats and their relationship to self-efficacy and implementation of a new teaching strategy. The Elementary School Journal, 110(2), 228-248.
• Uzun, S., Bütüner, S. E. &Yiğit, N. (2010). A comparison of the results of TIMSS 1999-2007: The most successful five countries-Turkey sample. Elementary Education Online, 9 (2), 1174-1188.
• Wang, J. (2007). A trend study of self-concept and mathematics achievement in a cross cultural context. Mathematics Education Research, 19(3), 33–47.
• Wang, J. (2005). Relationship between mathematics and science achievement at the 8th grade. International Online Journal of Science Mathematics Education, 5, 1–17.
• Wilkins, J. L. (2004). Mathematics and science self-concept: An international investigation. Journal of Experimental Education, 72, 331–346.
• Wilson, P. S. (1971). Interest and discipline in education. London: Routledge and Kegan Paul Ltd.
• Wright, M., & Corin, A. (1999). Mathematics and science. Report to the division of mathematical sciences. Arlington, VA: National Science Foundation.
• Yaman, M., Gerçek, S., & Soran, H. (2008). Analysis of biology teacher candidates’ occupational interests in terms of different variables. Hacettepe University Journal of Education, 35, 351–361.
• Yüksel-Şahin, F. (2008). Mathematics anxiety among 4th and 5th grade Turkish elementary school students. International Electronic Journal of Mathematics Education, 3(3), 179–192.
• Zadeh, L. A. (1965). Fuzzy sets. Information and Control, 8, 338–353.
• Zakaria, E., & Nordin, N. M. (2008). The effects of mathematics anxiety on matriculation students as related to motivation and achievement. Eurasia Journal of Mathematics, Science & Technology Education, 4(1), 27–30.
• Zimmerman, B. J., Bonner, S., & Kovach, R. (1996). Developing self-regulated learners beyond achievement to self-efficacy. Washington, DC: American Psychological Association.