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研究生: 李亞橋
Lee, Ya-Chiao
論文名稱: 教師提問在引導式探究教學中的角色:台灣與澳洲科學教室跨國比較
The role of teacher questioning in guided scientific inquiry learning: a cross-national comparison of Taiwan and Australia science classrooms
指導教授: 甄曉蘭
Chen, Hsiao-Lan
學位類別: 碩士
Master
系所名稱: 課程與教學研究所
Graduate Institute of Curriculum and Instruction
論文出版年: 2016
畢業學年度: 104
語文別: 英文
論文頁數: 147
中文關鍵詞: 教師提問科學探究學習跨國比較
英文關鍵詞: Guided Inquiry, Teacher Questioning, Cross-National Comparison
DOI URL: https://doi.org/10.6345/NTNU202204017
論文種類: 學術論文
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  • 在教室對話中,有效的教師提問扮演重要角色來刺激學生進行思考、建立鷹架以及發展出學生的科學探究能力。然而,一般教師在使用提問引導學生進行科學探究與科學推理過程中,面臨諸多困難,以至於難以落實探究教學。此研究針對一位台灣與一位澳洲之國小自然科經驗教師,探討此二位經驗教師如何使用提問引導與促進學生進行探究學習。透過跨國之比較研究,目的為了解探究教學中建立有效提問之因素為何,以及當中文化與課程內容如何影響與形塑出教師的提問方式。此研究中發展出一「引導式探究學習中的提問類型模式」分析架構,呈現探究教學中教師的提問具有不同功能,包括:「確認」、「激發」、「釐清」、「連結」與「延伸」。本研究透過教學錄影分析台灣個案教師「簡單機械」單元與澳洲個案教師「飛行與地心引力」單元,探討教師提問的模式、提問背後的想法與設計,以及透過比較了解文化與課程內容對於教師提問的影響,以提供未來教師引導式探究教學之指引參考。研究結果提出四個在引導式探究教學中,教師提問的主要功能包含建立科學概念、產生連結、釐清想法與強化及應用。此外,研究比較二位經驗教師之教學特色,台灣教師之教學較為結構化,並使用較多閉鎖式提問;澳洲教師之教學較有彈性,並使用較多開放性提問。然而,兩種教學特徵透過教師純熟的發揮,皆能夠提供學生良好的引導,並能幫助學生進行探究學習。根據研究發現,本研究提出了相關教學啟示與研究建議。

    Effective teacher questioning and classroom discourse play important roles in stimulating, scaffolding students’ thoughts and developing students’ scientific inquiry skills. However, teachers may not know how to provide guided questions to stimulate inquiry learning in science classrooms. With an attempt to explore the role of teacher questioning in inquiry learning, this study examines how experienced elementary science teachers in Taiwan and Australia use questioning to guide students’ learning in their inquiry-based science teaching. Through cross-national comparison, this study aims to understand important factors that contribute to effective teacher questioning while trying to capture the impact of cultural and curriculum contexts on the framing of inquiry processes. A framework of questioning in guided scientific inquiry learning was developed to analyze teacher’s questioning patterns, showing different forms of questioning according to its function: confirmation, stimulation, clarification, connection and extension. Based on video analysis of two case teacher’s science classrooms interactions, results indicate building concept, making connections, clarifying thoughts, and reinforcing application are four main functions of teacher questioning to guide inquiry learning. Although two case teachers are varied in instructional characteristics, from structured to flexible designs and closed to open questions, they both provided clear guidance in their teaching to help students getting engaged in inquiry learning. Also, implications and suggestions are provided for pedagogical practice and further study in science teaching and learning.

    ACKNOWLEDGEMENTS……………………………………………………………I CHINESE ABSRACT………………………………………………………..III ENGLISH ABSRACT………………………………………………….…….IV TABLE OF CONTENTS……………………………………………..………………. V LIST OF TABLES……………………………………………………..VIII LIST OF FIGURES……………………………………………………………IX CHAPTER ONE: INTRODUCTION …………………………………………………1 Introduction…………………..……………………………………………………1 Research Purpose and Questions……………………………………………………8 Definition of Terms……………………………………………………………….9 Significance of the study………………………………………………………….10 Limitations of the study…………………………………………………………..11 CHAPTER TWO: REVIEW OF RESEARCH LITERATURE………………………13 Inquiry in science classroom………………………………………………………14 The nature of scientific inquiry…………………………………………14 Science teaching and scientific inquiry…………………………………17 The significance of guided inquiry in science classroom…………………….21 Teacher questioning for science learning……………………………22 The importance of teacher questioning………………………………………23 The types of teacher questioning…………………………………………24 Challenges of questioning in science classroom………………28 Understanding science teaching and learning cross-nationally……………………29 Values of cross-national comparative studies………………………30 Cross-national comparative studies in science teaching……………………32 Cross-national comparison between Taiwan and Australia in science teaching…………………………………………….………………………..33 CHAPTER THREE: METHODOLOGY……………………………………………35 Brief introduction of EQALPRIME methodology ……………………………36 Sampling………………………………………………………..…………36 Data collection and analysis…………………………………………….38 Research design of this study ………………………………….……………..40 Case selection …………………………………….…………………..…40 Background of case teachers ……………………………………………42 Data collection and management………………………………………..43 Data analysis …………………………………….……………..………45 The validation process…………………………………………………51 CHAPTER FOUR: RESULTS AND DISCUSSIONS……………………………..53 Case teachers’ beliefs and their instructional plans ………………………………53 Questioning patterns of the case teachers …………………………………………68 Functional use of questioning in case teacher’s guided inquiry …………………87 The role of questioning in case teacher’s teaching………………………………102 CHAPTER FIVE: CONCLUSIONS AND RECOMMANDATIONS……………….112 Conclusions………………………………..………………………………112 Implications……..……………………………………………………………119 LIST OF REFERENCES……………………………………………………………..124 APPENDEX…………………………………………………………………….…….132 APPENDEX A: Outline of Australia case teacher interview in this study……132 APPENDEX B: Outline of Taiwan case teacher interview in this study………134 APPENDEX C: Taiwan case teacher’s instructional plans……………………135 APPENDEX D: Australia case teacher’s instructional plans……………………..139

    Aldridge, J. M., Fraser, B. J., Taylor, P. C., & Chen, C. C. (2000). Constructivist learning environments in a crossnational study in Taiwan and Australia. International Journal of Science Education, 22(1), 37-55.
    Aldridge, J., & Fraser, B. (2000). A cross-cultural study of classroom learning environments in Australia and Taiwan. Learning Environments Research, 3(2), 101-134.
    Anderson, R. D. (2002). Reforming Science Teaching: What Research Says About Inquiry. Journal of Science Teacher Education, 13(1), 1-12.
    Auyeung, P., & Sands, J. (1996). A cross cultural study of the learning style of accounting students. Accounting & Finance, 36(2), 261-274.
    Banchi, H., & Bell, R. (2008). THE MANY LEVELS OF inquiry. Science and Children, 46(2), 26-29.
    Bevevino, M. M., Dengel, J., & Adams, K. (1999). Constructivist theory in the classroom internalizing: Concepts through inquiry learning. The Clearing House, 72(5), 275-278.
    Bloom, B. S., (Ed.) 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: David McKay.
    Bybee, R. W. (2004). Scientific inquiry and science teaching. In Scientific inquiry and nature of science (pp. 1-14). Springer Netherlands.
    Carlsen, W. S. (1991). Questioning in classrooms: A sociolinguistic perspective. Review of Educational Research, 61(2), 157-178.
    Chang, C. Y., & Mao, S. L. (1999). Comparison of Taiwan science students’ outcomes with inquiry-group versus traditional instruction. The Journal of Educational Research, 92, 340-346.
    Chin, C. (2006). Classroom interaction in science: Teacher questioning and feedback to students’ responses. International journal of science education, 28(11), 1315-1346.
    Chin, C. (2007). Teacher questioning in science classrooms: Approaches that stimulate productive thinking. Journal of Research in Science Teaching, 44(6), 815-843.
    Clarke, D., & Suri, H. (2003). Issues of voice and variation: Developments in international comparative research in mathematics education. In Paper presented as part of the symposium “Mathematics Lessons in Germany, Japan, the USA and Australia: Structure in Diversity and Diversity in Structure” at the Annual Meeting of the American Educational Research Association, Chicago.
    Crawford, B. A., Zembal‐Saul, C., Munford, D., & Friedrichsen, P. (2005). Confronting prospective teachers' ideas of evolution and scientific inquiry using technology and inquiry‐based tasks. Journal of Research in Science Teaching, 42(6), 613-637.
    Fraser, B. J., Aldridge, J. M., & Adolphe, F. G. (2010). A cross-national study of secondary science classroom environments in Australia and Indonesia. Research in Science Education, 40(4), 551-571.
    Friedrichsen, P. M., Munford, D., & Orgill, M. (2006). Brokering at the boundary: A prospective science teacher engages students in inquiry. Science Education, 90(3), 522-543.
    Furtak, E. M. (2006). The problem with answers: An exploration of guided scientific inquiry teaching. Science Education, 90(3), 453-467.
    Furtak, E. M., & Ruiz‐Primo, M. A. (2008). Making students' thinking explicit in writing and discussion: An analysis of formative assessment prompts. Science Education, 92(5), 799-824.
    Gall, M. (1984). Synthesis of research on teachers' questioning. Educational leadership, 42(3), 40-47.
    Gunstone, R. F., Loughran, J. J., Berry, A., & Mulhall, P. (1999). Inquiry in Science Classes--Do We Know" How, When and Why"?.
    Herron, M.D. 1971. The nature of scientific inquiry. School Review, 79(2), 171–212.
    Hiebert, J., & Stigler, J. W. (2000). A proposal for improving classroom teaching: Lessons from the TIMSS video study. The Elementary School Journal, 101, 3-20.
    Hofstein, A., Navon, O., Kipnis, M., & Mamlok‐Naaman, R. (2005). Developing students' ability to ask more and better questions resulting from inquiry‐type chemistry laboratories. Journal of research in science teaching, 42(7), 791-806.
    Hwang, G. J., Chu, H. C., Shih, J. L., Huang, S. H., & Tsai, C. C. (2010). A decision-tree-oriented guidance mechanism forconducting nature science observation activities in a context-aware ubiquitous learning environment. Educational Technology & Society, 13(2), 53-64.
    Hwang, G. J., Yang, T. C., Tsai, C. C., & Yang, Stephen J. H. (2009). A context-aware ubiquitous learning environment for conducting complex experimental procedures. Computers & Education, 53, 402-413.
    Jones, M. T., & Eick, C. J. (2007). Implementing inquiry kit curriculum: Obstacles, adaptations, and practical knowledge development in two middle school science teachers. Science Education, 91(3), 492-513.
    Keys, C. W., & Kennedy, V. (1999). Understanding inquiry science teaching in context: A case study of an elementary teacher. Journal of Science Teacher Education, 10(4), 315-333.
    Koksal, E. A., & Berberoglu, G. (2014). The Effect of Guided-Inquiry Instruction on 6th Grade Turkish Students' Achievement, Science Process Skills, and Attitudes Toward Science. International Journal of Science Education, 36(1), 66-78.
    Krajcik, J. S., Blumenfeld, P. C., Marx, R. W., Bass, K. M., Fredricks, J., & Soloway, E. (1998). Inquiry in project-based science classrooms: initial attempts by middle school students. Journal of the Learning Sciences, 7(3&4), 313–350.
    Kuhlthau, C. C. (1991). Inside the search process: Information seeking from the user's perspective. JASIS, 42(5), 361-371.
    Kuhlthau, C. C. (2010) Guided Inquiry: school libraries in the 21st century, School Libraries Worldwide, 16(1), 17–28.
    Kuhlthau, C. C., L. K. Maniotes, and A. K. Caspari. (2007). Guided Inquiry: Learning in the 21st Century. Westport, CT: Libraries Unlimited.
    Kuhn, D., Black, J., Keselman, A., & Kaplan, D. (2000). The development of cognitive skills to support inquiry learning. Cognition and Instruction, 18(4), 495-523.
    Liu, T. C., Peng, H., Wu, W. H., & Lin, M. S. (2009). The effects of mobile natural-science learning based on the 5E learning cycle: a case study. Educational Technology & Society, 12(4), 344–358.
    Löfgren, R., Schoultz, J., Hultman, G., & Bjorklund, L. (2013) Exploratory talk in science education: Inquiry-based learning and communicative approach in primary school. Journal of Baltic Science Education, 12(4) 482-496
    Looi, C. K., Zhang, B. B., Chen, W. W., Seow, P. P., Chia, G. G., Norris, C. C., & Soloway, E. E. (2011). 1:1 mobile inquiry learning experience for primary science students: a study of learning effectiveness. Journal of Computer Assisted Learning, 27(3), 269-287.
    Martin-Hansen, L. (2002). Defining inquiry. The Science Teacher, 69(2), 34.
    McConney, A., Oliver, M. C., Woods-McConney, A., Schibeci, R., & Maor, D. (2014). Inquiry, engagement, and literacy in science: A retrospective, cross-national analysis using PISA 2006. Science Education, 98(6), 963-980. doi:10.1002/sce.21135
    Ministry of Education of Singapore. (2014). Primary Science Syllabus. Ministry of Education of Singapore: Curriculum Planning & Development Division.
    Mortimer, E., & Scott, P. (2003). Meaning Making In Secondary Science Classrooms. Maidenhead, UK: Open University Press.
    National Research Council. (2000). Inquiry and the national science education standards: A guide for teaching and learning. Washington, DC: National Academies Press.
    Nowak, K. H., Nehring, A., Tiemann, R., & Upmeier zu Belzen, A. (2013). Assessing students’ abilities in processes of scientific inquiry in biology using a paper-and-pencil test. Journal of Biological Education, 47(3), 182-188.
    Oliveira, A. W. (2010a). Developing elementary teachers understanding of the discourse structure of inquiry-based science classrooms. International Journal of Science and Mathematics Education, 8(2), 247-269.
    Oliveira, A. W. (2010b). Improving teacher questioning in science inquiry discussions through professional development. Journal of Research in Science Teaching, 47(4), 422-453.
    Omar, O. (2009). Teachers’ questioning techniques and their potential in heightening pupils’ inquiry. Kennedy, K. J (Chair), International Conference on Primary Education 2009. Hong Kong Institute of Education.
    Palincsar, A. S., Collins, K. M., Marano, N. L., & Magnusson, S. J. (2000). Investigating the engagement and learning of students with learning disabilities in guided inquiry science teaching. Language, Speech, and Hearing Services in Schools, 31(3), 240-251.
    Ramseger, J. (2014). Criteria for quality in science education – a German perspective. Guo, C. J (Chair), Cross-national comparison of quality teaching in primary science education. Symposium conducted at the meeting of College of education, NTNU.
    Redfield, D. L., & Rousseau, E. W. (1981). A meta-analysis of experimental research on teacher questioning behavior. Review of educational research, 51(2), 237-245.
    Roehrig, G. H., & Luft, J. A. (2004). Constraints experienced by beginning secondary science teachers in implementing scientific inquiry lessons. International Journal of Science Education, 26(1), 3-24.
    Romey, W. D. (Ed.). (1968). Inquiry techniques for teaching science. Prentice Hall Inc, NJ.
    Roth, W. M. (1996). Teacher questioning in an open‐inquiry learning environment: Interactions of context, content, and student responses. Journal of Research in Science Teaching, 33(7), 709-736.
    Ruiz‐Primo, M. A., & Furtak, E. M. (2007). Exploring teachers' informal formative assessment practices and students' understanding in the context of scientific inquiry. Journal of research in science teaching, 44(1), 57-84.
    Schwartz, R. S., Lederman, N. G., & Crawford, B. A. (2004). Developing views of nature of science in an authentic context: An explicit approach to bridging the gap between nature of science and scientific inquiry. Science education, 88(4), 610-645.
    Schweingruber, H. A., Duschl, R. A., & Shouse, A. W. (Eds.). (2007). Taking Science to School: Learning and Teaching Science in Grades K-8. National Academies Press.
    Smith, C. L., Maclin, D., Houghton, C., & Hennessey, M. G. (2000). Sixth-grade students’ epistemologies of science: the impact of school science experiences on epistemological development. Cognition and Instruction, 18(3), 3349–3422.
    Song, Y. (2014). “Bring Your Own Device (BYOD)” for seamless science inquiry in a primary school. Computers & Education, 74, 50-60.
    Song, Y., & Kong, S. C. (2014). Going beyond textbooks: a study on seamless science inquiry in an upper primary class. Educational Media International, 51(3), 226-236.
    Stigler, J. W., & Hiebert, J. (1999). The teaching gap: Best ideas from the world's teachers for improving education in the classroom. New York: The Free Press.
    Stigler, J. W., Gallimore, R., & Hiebert, J. (2000). Using video surveys to compare classrooms and teaching across cultures: Examples and lessons from the TIMSS video studies. Educational Psychologist, 35(2), 87-100.
    Stigler, J., & Hiebert, J. (1997). Understanding and improving classroom mathematics instruction: An overview of the TIMSS video study. In ACER National Conference 1997 (pp. 52-65).
    Trundle, K. C., Atwood, R. K., Christopher, J. E., & Sackes, M. (2010). The effect of guided inquiry-based instruction on middle school students’ understanding of lunar concepts. Research in Science Education, 40(3), 451-478.
    Tytler, R., & Aranda, G. (2015). Expert teachers’ discursive moves in science classroom interactive talk. International Journal of Science and Mathematics Education, 13(2), 425-446.
    van Zee, E. H., Iwasyk, M., Kurose, A., Simpson, D., & Wild, J. (2001). Student and teacher questioning during conversations about science. Journal of Research in Science Teaching, 38(2), 159-190.
    Walsh, J. A., & Sattes, B. D. (2004). Quality questioning: Research-based practice to engage every learner. Corwin Press.
    Walsh, J., & Sattes, B. (2011). Thinking through quality questioning. Thousand Oaks, CA.
    Welch, W. W., Klopfer, L. E., Aikenhead, G. S., & Robinson, J. T. (1981). The role of inquiry in science education: Analysis and recommendations. Science education, 65(1), 33-50.
    Wragg, E. C., & Brown, G. A. (2002). Questioning in the primary school. Routledge.
    Wu, H. K., & Hsieh, C. E. (2006). Developing sixth graders' inquiry skills to construct explanations in inquiry-based learning environments. International Journal of Science Education, 28, 1289–1313.
    Wu, H. K., & Wu, C. L. (2011). Exploring the development of fifth graders’ practical epistemologies and explanation skills in inquiry-based learning classrooms. Research in Science Education, 41(3), 319-340.
    Yip, D. Y. (2004). Questioning skills for conceptual change in science instruction. Journal of Biological Education, 38(2), 76-83.

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