Abstract
This study focuses on elucidating and explaining reasons for the stability of and interrelationships between students’ conceptions about Light Propagation and Visibility of Objects using contextualized questions across 3 years of secondary schooling from Years 7 to 9. In a large-scale quantitative study involving 1,233 Korean students and 1,149 Singaporean students, data were analyzed from responses to the Light Propagation Diagnostic Instrument consisting of four pairs of items, each of which evaluated the same concept in two different problem situations. Findings show that only about 10–45 % of students could apply their conceptions of basic optics in contextualized problem situations giving rise to both stable and unstable alternative conceptions. Students’ understanding of Light Propagation concepts compared with Visibility of Objects concepts was more stable in different problem situations. The concepts of Light Propagation and Visibility of Objects were only moderately correlated. School grade was not a strong predictive variable, but students’ school achievement correlated strongly with their conceptual understanding in optics. The teaching and learning approach and education systems in the two countries may have had some influence on students’ conceptual understanding.
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References
Abell KS, Lederman GN (eds) (2007) Handbook of research on science education. Routledge, New York
Anderson CW (2007) Perspective in science learning. In: Abell SK, Lederman NG (eds) Handbook of research on science education. Lawrence Erlbaum, Mahwah, pp 3–56
Anderson B, Karrqvist C (1981) Light and its properties. In: Driver R, Squires A, Rushworth P, Wood-Robinson V (eds) Making sense of secondary science. Routledge Falmer, London, pp 41–47
Birk JP, Kurtz MJ (1999) Effect of experience on retention and elimination of misconceptions about molecular structure and bonding. J Chem Educ 76:124–128
Brislin WR (1970) Back-translation for cross-cultural research. J Cross Cultural Psychol 1(3):185–216
Byun S-Y, Kim K–K (2010) Educational inequality in South Korea: the widening socioeconomic gap in student achievement. Res Sociol Educ 17:155–182
Chang H-P, Chen J-Y, Guo C-J, Chen C–C, Chang C-Y, Tseng Y-T (2007) Investigating primary and secondary students’ learning of physics concepts in Taiwan. Int J Sci Educ 29(4):465–482
Clough EE, Driver R (1986) A study of consistency in the use of students’ conceptual frameworks across different task contexts. Sci Educ 70(4):473–496
Cohen J (1988) Statistical power analysis for the behavioral sciences. Hillsdale, NJ: Erlbaum
Driver R, Guesne E, Tiberghien A (1985) Children’s ideas and the learning of science. In: Driver R et al (eds) Children’s ideas in science. Open University Press, Philadelphia, pp 10–32
Driver R, Squires A, Rushworth P, Wood-Robinson V (1994) Making sense of secondary science: research into children’s ideas. Rutledge, London
Duit R (2009) Bibliography: students’ and teachers’ conceptions and science education. http://www.ipn.uni-kiel.de/aktuell/stcse/stcse.html. Accessed 1 July 2012
Duit R, Treagust DF (1998) Learning in science—from behaviorism towards social constructivism and beyond. In: Fraser B, Tobin K (eds) International handbook of science education, part 1. Kluwer, Dordrecht, pp 3–25
Fensham JP (2009) Real world contexts in PISA science: implications for context-based science education. J Res Sci Teach 46(8):884–896
Fetherstonhaugh T, Treagust DF (1992) Students’ understanding of light and its properties: teaching to engender conceptual change. Sci Educ 76(6):653–672
Fraser BJ, Tobin K, McRobbie CJ (eds) (2012) Second international handbook of science education. Springer, New York
Galili I (1996) Students’ conceptual change in geometrical optics. Int J Sci Educ 18(7):847–868
Galili I, Hazan A (2000) Learner’s knowledge in optics: interpretation, structure and analysis. Int J Sci Educ 22(1):57–88
Hubber P, Tytler R, Haskam F (2010) Teaching and learning about force with a representational focus: pedagogy and teacher changes. Res Sci Educ 40(1):5–28
Jung W (1987) Understanding students’ understanding: the case of elementary optics. In: Novak JD (ed) Proceedings of second international seminar: misconceptions and educational strategies in science and mathematics, vol III. Cornell University, Ithaca, pp 268–277
Kim SS (2010) 2009 assessment analysis of academic achievement: Regional differences and school characteristics. The 5th education curriculum and assessment policy forum, ORM 2010–2014. Korean Institute of Curriculum and Evaluation (KICE), Seoul
King D, Ritchie S (2012) Learning science through real-world contexts. In: Fraser BJ, Tobin K, McRobbie CJ (eds) Second international handbook of science education. Springer, New York, pp 69–79
La Rosa C, Mayer M, Patrizi P, Vicentini-Missoni M (1984) Commonsense knowledge in optics: preliminary results of an investigation into the properties of light. Eur J Sci Educ 6(4):387–397
Langley D, Ronen M, Eylon B-S (1997) Light propagation and visual patterns: preinstruction learners’ conceptions. J Res Sci Teach 34(4):399–424
Lee H-M (1998) The impact of regional differences on secondary school students’ academic achievement. Ment Cultural Stud 21(3):109–136
Ministry of Education (MOE) (2004) Science syllabus—primary. Curriculum Planning and Development Division, MOE, Singapore
Ministry of Education (MOE) (2007) Science syllabus—lower secondary. Curriculum Planning and Development Division, MOE, Singapore
Ministry of Education and Human Resource Development (MOE and HRD) (2007) Science and curriculum. MOE and HRD, Seoul
Nunally JC, Bernstein IH (1994) Psychometric theory, 3rd edn. McGraw Hill, New York
Odom AL, Barrow LH (1995) Development and application of a two-tier diagnostic test measuring college biology students’ understanding of diffusion and osmosis after a course of instruction. J Res Sci Teach 32(1):45–61
Peat J (2001) Health science research: a handbook of quantitative methods. Allen and Unwin, Sydney
Peterson RF, Treagust DF, Garnett P (1989) Development and application of a diagnostic instrument to evaluate grade 11 and 12 students’ concepts of covalent bonding and structure following a course of instruction. J Res Sci Teach 26:301–314
Ramadas J, Driver R (1989) Aspects of secondary students’ ideas about light. Center for Studies in Science and Mathematics Education, University of Leeds, Leeds
Saxena AB (1991) The understanding of the properties of light by students in India. Int J Sci Educ 13(3):283–289
Scott P, Asoko H, Leach J (2007) Student conceptions and conceptual learning in science. In: Abell S, Lederman N (eds) Handbook of research on science education. Erlbaum, Mahwah, pp 31–56
Shapiro BL (1989) What children bring to light: giving high status to learners’ views and actions in science. Sci Educ 73(6):711–733
Shelley NJ (1996) Towards a phenomenography of light and vision. Int J Sci Educ 18(7):837–846
Singley MK, Anderson JR (1989) The transfer of cognitive skill. Harvard University Press, Cambridge
Tan DK-C, Treagust DF (1999) Evaluating students’ understanding of chemical bonding. School Sci Rev 81(294):75–83
Tan KCD, Goh NK, Chia LS, Treagust DF (2002) Development and application of a two-tier multiple choice diagnostic instrument to assess high school students’ understanding of inorganic chemistry qualitative analysis. J Res Sci Teach 39(4):283–301
Tao P-K, Gunstone RF (1999) The process of conceptual change in force and motion during computer-supported physics instruction. J Res Sci Teach 36(7):859–882
Treagust DF (1995) Diagnostic assessment of students’ science concepts. In: Glynn S, Duit R (eds) Learning science in the schools: research reforming practice. Lawrence Erlbaum Associates, Mahwah, pp 327–346
Treagust DF (1988) The development and use of diagnostic instruments to evaluate students’ misconceptions in science. Int J Sci Educ 10:159–169
Treagust DF (2006) Diagnostic assessment in science as a means to improving teaching, learning and retention. UniServe science assessment symposium proceedings. http://science.uniserve.edu.au/pubs/procs/2006/treagust.pdf. Accessed 28 May 2013
Treagust DF, Chandrasegaran AL (2007) The Taiwan national science concept learning study in an international perspective. Int J Sci Educ 29(4):391–403
Treagust DF, Chiu M-H, Guo C-G (Eds) (2007) Taiwan National science concept learning study: a large scale assessment project using two-tier diagnostic tests. International Journal of Science Education (special issue) 29(4)
Tytler R (1998) The nature of students’ informal science conceptions. Int J Sci Educ 20(8):901–927
Tytler R, Peterson S (2004) From “try it and see” to strategic exploration: characterizing young children’s scientific reasoning. J Res Sci Teach 41(1):84–118
University of Cambridge International Examinations (CIE) (2009) Cambridge O level physics: syllabus code 5054. http://www.cie.org.uk/qualifications/academic/middlesec/olevel/overview. Accessed 28 May 2011
Wandersee JH, Mintzes JJ, Novak JD (1994) Research on alternative conceptions in science. In: Gabel DL (ed) Handbook of research on science teaching and learning. Macmillan, New York, pp 177–210
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Chu, HE., Treagust, D.F. Secondary Students’ Stable and Unstable Optics Conceptions Using Contextualized Questions. J Sci Educ Technol 23, 238–251 (2014). https://doi.org/10.1007/s10956-013-9472-6
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DOI: https://doi.org/10.1007/s10956-013-9472-6