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The core practice of professional scientists is inquiry, often referred to as research. If educators are to prepare students for a role in the professional scientific and technological community, exposing them to inquiry-based learning is essential. Despite this, inquiry-based teaching and learning (IBTL) remains relatively rare, possibly due to barriers that teachers face in deploying it or to a lack of belief in the teaching community that inquiry-based learning is effective. Comparative Perspectives on Inquiry-Based Science Education examines stories and experiences from members of an international science education project that delivered learning resources based around guided inquiry for students to a wide range of schools in 12 different countries in order to identify key themes that can provide useful insights for student learning, teacher support, and policy formulation at the continental level. The book provides case studies across these 12 different settings that enable readers to compare and contrast both practice and policy issues with their own contexts while accessing a cutting-edge model of professional development. It is designed for educators, instructional designers, administrators, principals, researchers, policymakers, practitioners, and students seeking current and relevant research on international education and education strategies for science courses.
This edited volume brings forth intriguing, novel and innovative research in the field of science education. The chapters in the book deal with a wide variety of topics and research approaches, conducted in various contexts and settings, all adding a strong contribution to knowledge on science teaching and learning. The book is comprised of selected high-quality studies that were presented at the 11th European Science Education Research Association (ESERA) Conference, held in Helsinki, Finland from 31 August to 4 September, 2015. The ESERA science education research community consists of professionals with diverse disciplinary backgrounds from natural sciences to social sciences. This diversity provides a rich understanding of cognitive and affective aspects of science teaching and learning in this volume. The studies in this book will invoke discussion and ignite further interest in finding new ways of doing and researching science education for the future and looking fo r international partners for both science education and science education research. The twenty-five chapters showcase current orientations of research in science education and are of interest to science teachers, teacher educators and science education researchers around the world with a commitment to evidence-based and forward-looking science teaching and learning.
Um erfolgreich forschend lernen zu können, müssen Schülerinnen und Schüler bestimmte Handlungsweisen erlernen und einüben. In einer Prä-Post-Studie zum Strategielernen wurden das hypothesengeleitete Experimentieren und die Control-of-Variables-Strategie zunächst vermittelt. Danach sollten diese Strategien in zwei Experimentierumgebungen, unterstützt durch z.B. Prompts, angewandt werden. Da sowohl reale Experimente als auch Computersimulationen zum Strategielernen eingesetzt werden können, wurden vier Treatmentgruppen (real-real, real-virtuell, virtuell-real, virtuell-virtuell) miteinander verglichen. Neben Kontrollvariablen wie kognitive Fähigkeiten und Motivation wurden prä-post das Fachwissen, Wissen zum Experimentieren und Wissen zum Strategieeinsatz gemessen. Während des Experimentierens wurden die Schülerinnen und Schüler (8. Klasse, Gymnasium, NRW) beobachtet, um herauszufinden, inwiefern sich das Arbeiten mit realen und virtuellen Experimenten unterscheidet und inwiefern diese Unterschiede eventuelle Unterschiede im Lernzuwachs erklären können. Die Ergebnisse zeigen, dass trotz sehr unterschiedlichen Arbeitens mit realen und virtuellen Experimenten alle Treatmentgruppen deutliche Lernzuwächse aufzeigen.
As part of an international curricular Delphi study, Theresa Schulte realizes an empirically based approach to a contemporary understanding of scientific literacy from the perspective of different stakeholders in Germany. The analyses show in which areas changes are necessary so that science education can better fulfill its claim to contribute to students’ general education and literacy.
Pedagogical Content Knowledge (PCK) has been adapted, adopted, and taken up in a diversity of ways in science education since the concept was introduced in the mid-1980s. Now that it is so well embedded within the language of teaching and learning, research and knowledge about the construct needs to be more useable and applicable to the work of science teachers, especially so in these times when standards and other measures are being used to define their knowledge, skills, and abilities. Re-examining Pedagogical Content Knowledge in Science Education is organized around three themes: Re-examining PCK: Issues, ideas and development; Research developments and trajectories; Emerging themes in PCK research. Featuring the most up-to-date work from leading PCK scholars in science education across the globe, this volume maps where PCK has been, where it is going, and how it now informs and enhances knowledge of science teachers’ professional knowledge. It illustrates how the PCK research agenda has developed and can make a difference to teachers’ practice and students’ learning of science.
This book is about mathematics in physics education, the difficulties students have in learning physics, and the way in which mathematization can help to improve physics teaching and learning. The book brings together different teaching and learning perspectives, and addresses both fundamental considerations and practical aspects. Divided into four parts, the book starts out with theoretical viewpoints that enlighten the interplay of physics and mathematics also including historical developments. The second part delves into the learners’ perspective. It addresses aspects of the learning by secondary school students as well as by students just entering university, or teacher students. Topics discussed range from problem solving over the role of graphs to integrated mathematics and physics learning. The third part includes a broad range of subjects from teachers’ views and knowledge, the analysis of classroom discourse and an evaluated teaching proposal. The last part describes approaches that take up mathematization in a broader interpretation, and includes the presentation of a model for physics teachers’ pedagogical content knowledge (PCK) specific to the role of mathematics in physics.
Practical work has been part of science education for just over 100 years and is accepted as an essential and exciting part of understanding this discipline. Although it can be costly and sometimes messy, it simply has to be done if students and teachers are to progress in their understanding. Schools and universities invest millions of pounds in it and the National Curriculum reveres it - but what exactly is going on in classrooms around the country and how are the leading practitioners moving with the times? This book attempts to reflect on the value and purpose of practical work as part of the scientific curriculum. Why are practical exercises so necessary and what do they contribute to the learning process? The chapters examine many issues such as: * how practical work is perceived by students and teachers * whether we will move on to the 'virtual lab' * the limitations of current 'hands-on' work and valuable alternatives to it * the connections between practical work in science education and 'authentic' science * what role experimentation plays in current educational practice. Jerry Wellington is Reader in Education at Sheffield University, and has taught science at all academic levels.
This book addresses challenges in the theoretically and empirically adequate assessment of competencies in educational settings. It presents the scientific projects of the priority program “Competence Models for Assessing Individual Learning Outcomes and Evaluating Educational Processes,” which focused on competence assessment across disciplines in Germany. The six-year program coordinated 30 research projects involving experts from the fields of psychology, educational science, and subject-specific didactics. The main reference point for all projects is the concept of “competencies,” which are defined as “context-specific cognitive dispositions that are acquired and needed to successfully cope with certain situations or tasks in specific domains” (Koeppen et al., 2008, p. 62). The projects investigate different aspects of competence assessment: The primary focus lies on the development of cognitive models of competencies, complemented by the construction of psychometric models based on these theoretical models. In turn, the psychometric models constitute the basis for the construction of instruments for effectively measuring competencies. The assessment of competencies plays a key role in optimizing educational processes and improving the effectiveness of educational systems. This book contributes to this challenging endeavor by meeting the need for more integrative, interdisciplinary research on the structure, levels, and development of competencies.
The Art of Teaching Science emphasizes a humanistic, experiential, and constructivist approach to teaching and learning, and integrates a wide variety of pedagogical tools. Becoming a science teacher is a creative process, and this innovative textbook encourages students to construct ideas about science teaching through their interactions with peers, mentors, and instructors, and through hands-on, minds-on activities designed to foster a collaborative, thoughtful learning environment. This second edition retains key features such as inquiry-based activities and case studies throughout, while simultaneously adding new material on the impact of standardized testing on inquiry-based science, and explicit links to science teaching standards. Also included are expanded resources like a comprehensive website, a streamlined format and updated content, making the experiential tools in the book even more useful for both pre- and in-service science teachers. Special Features: Each chapter is organized into two sections: one that focuses on content and theme; and one that contains a variety of strategies for extending chapter concepts outside the classroom Case studies open each chapter to highlight real-world scenarios and to connect theory to teaching practice Contains 33 Inquiry Activities that provide opportunities to explore the dimensions of science teaching and increase professional expertise Problems and Extensions, On the Web Resources and Readings guide students to further critical investigation of important concepts and topics. An extensive companion website includes even more student and instructor resources, such as interviews with practicing science teachers, articles from the literature, chapter PowerPoint slides, syllabus helpers, additional case studies, activities, and more. Visit http://www.routledge.com/textbooks/9780415965286 to access this additional material.