Titel: Research in Science Education - Past, Present, and Future
Herausgegeben von Helga Behrendt, Helmut Dahncke, Reinders Duit
31. Januar 2001 - gebunden - 356 Seiten
This volume includes a selection of contributions to the Second Conference of the European Science Education Research Association held in Kiel, in September 1999. The aim of the conference was to provide a state-of-the-art view of science education research in Europe and also worldwide by looking at what has been achieved in the past decades and what has to be done in the coming years. In the first part of the volume, views and visions of science education research are discussed. The subsequent parts deal with research on scientific literacy, on students' and teachers' conceptions, on conceptual change, and on instructional media and lab work. The volume focuses not only on research in Europe but provides a truly international perspective with contributions by researchers from around the world.
Preface. Part 1: Views and Visions of Science Education Research. Science Education Researchers and Research in Transition: Issues and Policies; D. Psillos. Research in Science Education in Europe: Retrospect and Prospect; E.W. Jenkins. Science Content as Problematic - Issues for Research; P.J. Fensham. Science Education Versus Science in the Academy: Questions - Discussion - Perspectives; H. Dahncke, et al. Part 2: Scientific Literacy - Conceptions and Assessment. The Assessment of Scientific Literacy in the OECD/PISA Project; W. Harlen , et al. Scientific Literacy: From Theory to Practice; W. Gräber, et al. Making Formative Use of a National Summative Assessment Regime; T.J. Russell, L. McGuigan. A Comparison of STS-Teaching and Traditional Physics Lessons - On the Correlation of Physics Knowledge and Taking Action; H. Dahncke, et al. Part 3: Students' Conceptions. On the Quantum Thinking of Physics Undergraduates; G. Ireson. Experiences with a Modern Course in Quantum Physics; G. Pospiech. Learning Process Studies in the Field of Fractals; M. Komorek, et al. Students' Understandings of their Internal Structure as Revealed by Drawings; M.J. Reiss, S.D. Tunnicliffe. Personal Context and Continuity of Human Thought; Recurrent Themes in a Longitudinal Study of Pupils' Understanding of Scientific Phenomena; G. Helldén. Entities of the World and Causality in Children's Thinking; V. Spiliotopoulou, P. Alevizos. Using Media Reports of Science Research in Pupils' Evaluation of Evidence; M. Ratcliffe, P. Fullick. Pupils' Perceptions of Science Education at Primary and Secondary School; B. Campbell. Part 4: Teachers' Conceptions. Teacher Professionalism and Change: Developing aProfessional Self Through Reflective Assessment; M. Lang. Formative Assessment Using Concept Cartoons: Initial Teacher Training in the UK; B. Keogh, et al. Teaching Chemical Equilibrium in Australian and German Senior High Schools; D.F. Treagust, W. Gräber. The Ideas of Spanish Primary Teachers about How to Develop an Understanding of Processes in Science and their Support in Textbooks; S. García-Barros, et al. Pre-service Elementary Teachers Constructing the Nature and Language of Science; J.A. Craven, et al. Combining Knowledge of Physics and Chemistry in Teaching: The Behaviour of a Narrow Jet of Water in the Presence of Charged Insulators; L. Kyyrönen, M. Ahtee. Intuitive Rules: A Theory and Its Implications to Mathematics and Science Teacher Education; P. Tsamir, et al. Part 5: Conceptual Change &endash; Teaching and Learning Processes. Conceptual Change Research and the Teaching of Science; S. Vosniadou. Rhetoric and Science Education; I. Martins, et al. Development of Complexity through Dealing with Physical Qualities: One Type of Conceptual Change? S. von Aufschnaiter. On the Micro-Structure of Analogical Reasoning: The Case of Understanding Chaotic Systems; J. Wilbers, R. Duit. Role-playing, Conceptual Change, and the Learning Process: A Case Study of 7th Grade Pupils; P.-L. Lehtelä. Concept Mapping as a Tool for Research in Science Education; H. Fischler, et al. The Need for and the Role of Metacognition in Teaching and Learning the Particle Model; P. Buck, et al. Evolving Mental Models of Electric Circuits; M.S. Steinberg, J.J. Clement. Two Models for a Physical Situation: the Case of Optics. Students' Difficulties, Teachers' viewpoints and Guidelines for a `Didactic Structure'; P.