References
- American Association for the Advancement of Science (AAAS). (1989). Science for all Americans. New York: Oxford University Press.
- American Association for the Advancement of Science (AAAS). (1993). Benchmarks for scientific literacy. New York: Oxford University Press.
- Anderson, T. H., West, C. K., Beck, D. P., Macdonell, E. S., & Frisbie, D. S. (1997). Integrating reading and science education: On developing and evaluating WEE science. Journal of Curriculum Studies, 29(6), 711-734. https://doi.org/10.1080/002202797183847
- Apedoe, X. S., Reynolds, B., Ellefson, M. R., & Schunn, C. D. (2008). Bringing engineering design into high school science classrooms: The heating/cooling unit. Journal of Science Education and Technology, 17(5), 454-465. https://doi.org/10.1007/s10956-008-9114-6
- Asunda, P. A. (2012). Standards for Technological Literacy and STEM Education Delivery Through Career and Technical Education Programs. Journal of Technology Education, 23(2), 44-60.
- Baek, S., Kim, J., Choi, S., Lee, Y., Choi, J., Yang, K., Jeong, K., Choi, J., Lee, S., Jun, M., & Kim, K. (2012). The development of curriculum for pre-service teachers of secondary school. Korea Foundation for the Advancement of Science and Creativity, 2012-27.
- Baek, Y., Park, H., Kim, Y., Noh, S., Park, J., Lee, J., Jeong, J., Choi, Y., & Han, H. (2011). STEAM education in Korea. Journal of Learner-Centered Curriculum and Instruction, 11(4), 149-171.
- Bevins, S. (2012). STEM: Moving the liberal arts education into the 21st century. Technology and Engineering Teacher, 71(4), 10-13.
- Bloom, B. S., Engelhart, M. D., Furst, E. J., Hill, W. H., & Krathwohl, D. R. (1956). Taxonomy of educational objectives: the classification of educational goals; Handbook I: Cognitive Domain New York, Longmans, Green.
- Brown, R., Brown, J., Reardon, K., & Merril, C. (2011). Understanding STEM: Current perceptions. Technology and Engineering Teacher,70(6), 5-9.
- Bybee, R. W. (2010). Advancing STEM education: A 2020 vision. Technology and Engineering Teacher, 70(1), 30-35.
- Choi, Y., Noh, J., Lee, B., Moon, D., Lee, M., Chang, Y., Park, G., Son, D., Lim, Y., & Lee, E. (2012). Development of STEAM curriculum model for cultivating of creative and integrative thinking person. Korean Technology Education Association, 12(3), 63-87. Retrieved from DBpia database.
- Czerniak, C. M. (2007). Interdisciplinary science teaching. In S. K. Abell & N. G. Lederman(Eds.), Handbook of research on science education (pp. 537-559). Mahwah, NJ: Lawrence Erlbaum Associates.
- Deal, D. (1994). A look at project AIMS. School Science and Mathematics, 94, 11-114. https://doi.org/10.1111/j.1949-8594.1994.tb12282.x
- Drake, S. M. (2007). Creating Standards-Based Integrated Curriculum: Aligning Curriculum, Content, Assessment, and Instruction. Corwin Press, A SAGE Publications Company. 2455 Teller Road, Thousand Oaks, CA 91320.
- Eger, J. M. (2011). National Science Foundation slowly Turning STEM to STEAM. Retrieved from http://www.huffingtonpost.com/john-m-eger/national-science-foundati_b_868449.html.
- Fullan M.(2001). The New meaning of educational change. N.Y & London: Teachers College, Columbia Unisity Press.
- Goldschmidt, P., & Jung, H. (2011). Evaluation of seeds of science/roots of reading: Effective tools for developing literacy through science in the early grades-unit on planets and moons. Los Angeles, CA: National Center for Research on Evaluation, Standards, and Student Testing (CRESST).
- Gresnigt, R., Taconis, R., Keulen, H., Gravemeijer, K., & Baartman, L. (2014). Promoting science and technology in primary education: a review of integrated curricula, Studies in Science Education, 50(1), 47-84. https://doi.org/10.1080/03057267.2013.877694
- Han, H. (2013). The analysis of research trends on STEAM instructional program and the development of mathematics-centered STEAM instructional program. Communications of mathematical education, 27(4), 523-545. https://doi.org/10.7468/jksmee.2013.27.4.523
- Hynes, M., Portsmore, M., Dare, E., Milto, E., Rogers, C., Hammer, D., & Carberry, A. (2011). Infusing engineering design into high school STEM courses. Retrieved from the National Center for Engineering and Technology Education website: http://ncete.org/flash/pdfs/Infusing%20Engineering%20Hynes.pdf
- Jo, S., Kim, H. (2013). An analysis of STEAM curriculum elements through the review of STEAM education literature. The Journal of Elementary Education, 18(0), 19-39.
- Kang, C., Lee, S., & Kang, K. (2013). Secondary school teachers' perception on STEAM education and their satisfaction on teachers' training program. Journal of Educational Studies, 15(2), 1-12.
- Kelley, T., Brenner, D. C., & Pieper, J. T. (2010). PLTW and Epics-High: Curriculum Comparisons to Support Problem Solving in the Context of Engineering Design. Retrieved from http://digitalcommons.usu.edu/ncete_cstudies/16/.
- Kim, B., & Kim, J. (2013). Development of analysis framework for exploring PCK type in STEAM education, Korean Technology Education Association, 13(2), 63-85.
- Kim, D., Kim, M., & Lee, W. (2013). Factors associated with the breadth of interest toward various subjects in a school curriculum. Korean Journal of Sociology of Education, 23(3), 31-58.
- Kim, J. (2011). A cubic model for STEAM education. Korean Technology Education Association, 11(2), 124-139.
- Kim, S., Chung, Y., Woo, A., & Lee, H. (2012). Development of a theoretical model for STEAM education. Journal of the Korean Association for Research in Science Education, 32(2), 388-403. https://doi.org/10.14697/jkase.2012.32.2.388
- Kwon, H., Park, K., & Lee, H. (2011). Integrative STEM (science, technology, engineering, and mathematics) education: Contemporary Trends and Issues. Secondary Education Research, 59(3), 729-762. https://doi.org/10.25152/ser.2011.59.3.729
- Lee, C. (2012). Recent trends and dilemma of STEM education in the United States. Korean Association of Practical Arts Education, 25(4), 101-122. Retrieved from DBpia database.
- Lee, D., Kim, K., & Lee, C. (2011). The recognition and needs by technology teachers about STEM education. Korean Technology Education Association, 11(2), 159-180.
- Lee, K., & Kim, K. (2012). Exploring the meanings and practicability of Korea STEAM education, The Journal of Elementary Education, 25(3), 55-81.
- Lee, M., & Cho, M. (2014). The suggestion of field applications based on the Multiple Menu Model for a STEAM curriculum. The Journal of Curriculum Studies, 32(1), 77-102.
- Lim, Y. (2012). Problems and ways to improve Korean STEAM education based on integrated curriculum. The Journal of Elementary Education, 25(4), 53-80.
- Massachusetts Department of Education. (2006). Massachusetts science and technology/engineering curriculum framework. Malden, MA: Retrieved from http://www.doe.mass.edu/frameworks/scitech/1006.pdf
- Merrill, C., & Daughty, J. (2010). STEM education and leadership: A mathematics and science partnership approach. Journal of Technology Education, Vol. 21(2), 21-34.
- Morrison, J. (2006). TIES STEM education monograph series, attributes of STEM education. The Student The School The Classroom. Retrieved from http://www.tiesteach.org/documents/Jans%20pdf%20Attributes_of_STEM_Education-1.pdf
- National Research Council (NRC). (2010). Exploring the intersection of science education and 2lst century skills: A workshop summary. Washington, DC: National Academies Press.
- National Science Board. (2007). A national action plan for addressing the critical needs of the U.S. science, technology, engineering and mathematics education system. Retrieved June 9, 2014: http://www.nsf.gov/nsb/documents/2007/stem_action.pdf
- NGSS (2013) Next Generation Science Standards: For States, By States. The Standards. The National Academy Press.
- Oh, H. (2012). An analysis of changes on the science teachers stages of concern on STEM education and STEM-PCK. Department of Science Education, Graduate School, Kyungpook National University
- Organization for Economic Co-operation and Development (OECD). (2006). Assessing scientific, reading and mathematical literacy: A framework for PISA 2006. aris: OECD.
- Park, H., Kim, Y., Noh, S., Lee, J., Jeong, J., Choi, Y., Han, H., & Baek, Y. (2012). Components of 4C-STEAM education and a checklist for the instructional design. Journal of Learner-Centered Curriculum and Instruction, 12(4), 533-557.
- Pitt, J. (2009). Blurring the boundaries - stem education and education for sustainable development. Design and Technology Education: An International Journal, 14(1), 37-48.
- Platz, J. (2007) How do you turn STEM into STEAM? Add the Arts!. Retrieved from http://www.oaae.net/index.php/en/resources/educator/stem-to-steam.
- Rennie, L. J., Venville, G. J., & Wallace, J. (2012a). Knowledge that counts in a global community: Exploring the contribution of integrated curriculum. London: Routledge.
- Rennie, L., Wallace, J., & Venville, G. (2012b). Exploring curriculum integration-why integrate? In Rennie, L., Venville, G., & Wallace, J.(ed.), Integrating science technology, engineering, and mathematics(pp. 1-11). London: Routledge.
- Romance, N. R., & Vitale, M. R. (2008, November 12). Perspectives for improving school instruction and learning: An interdisciplinary model for integrating science and reading in grades K-5. Paper presented at the Committee on Education Workshop on Education Lecture Series, University of Chicago, Chicago, IL.
- Sanders, M. (2009). STEM, STEM Education, STEM mania. the Technology Teacher, 68(4), 20-26.
- Sanders, M. (2012). Integrative STEM education as " best practice". Paper presented at 7th biennial International Technology Education Research Conference. Queensland, Australia.
- Sheppard, S. D., Macatangay, K., Colby, A., & Sullivan, W. M. (2009). Educating engineers: Designing for the future of the field. San Francisco: Jossey-Bass.
- Son, Y., Jung, S., K, S., Kim, H., & Kim, D. (2012). Analysis of prospective and in-service teachers'awareness of STEAM convergent education. Studies in Humanities and Social Sciences, 13(1), 255-284. https://doi.org/10.15818/ihss.2012.13.1.255
- Tarnoff, J. (2010). STEM to STEAM-recognizing the value of creative skills in competitiveness debate. Retrieved from http://www.huffingtonpost.com/join-tarnoff/stem-to-steeam-recognizing_b_756519.html.
- Tsupros, N., Kohler, R. & Hallinen, J. (2009). STEM education: A project to identify the missing components, Intermediate Unit 1 and Carnegie Mellon, Pennsylvania.
- Venville, G. J., Wallace, J., Rennie, L. J., & Malone, J. A. (2002). Curriculum integration: Eroding the high ground of science as a school subject? Studies in Science Education, 37, 43-84. https://doi.org/10.1080/03057260208560177
- Wicklein, R. C. (2006). Five good reasons for engineering design as the focus for technology education. The Technology Teacher, 65(7), 25-29.
- Williams, P. J. (2011). Stem education: Proceed with caution. Design and Technology Education, 16(1), 26-35.
- Williams, P. J. (2010). Musings about Technology and Engineering Education. Journal of Technology Education, 21(2), 2-9.
- Yakman, G. (2011). Introducing teaching STEAM as a practical educational framework for Korea. STEAM Education International Seminar and STEAM teachers orientation workshops. Korea Foundation for the Advancement of Science and Creativity, 2012-27.
- Yakman, G. (2008). STE@M Education: An overview of creating a model of integrative education. Retrieved from http://steamedu.com/wp-content/uploads/2014/12/2008-PATT-Publication-STEAM.pdf.
- Zakaria, F. (2015). Why America's obssession with STEM education is dangerous. The Washington Post.
- Zollman, A. (2012). Learning for STEM Literacy: STEM Literacy for Learning. School Science and Mathematics, 112(1), 12-19. https://doi.org/10.1111/j.1949-8594.2012.00101.x
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