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  • 1
    Online Resource
    Online Resource
    Science Teachers’ Use of Visual Representations (2014)
    Dordrecht : Springer
    Details
    ISBN: 9783319065267
    Language: English
    Pages: Online-Ressource (VIII, 338 p. 65 illus, online resource)
    Series Statement: Models and Modeling in Science Education 8
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Druckausg. Science teachers' use of visual representations
    RVK:
    DP 4600
    RVK:
    ZX 7240
    RVK:
    TB 4056
    RVK:
    DP 1960
    RVK:
    AL 34330
    Keywords: Science Study and teaching ; Education ; Education ; Science Study and teaching ; Education ; Science Study and teaching ; Aufsatzsammlung ; Hochschule ; Lehre ; Visualisierung
    Abstract: This book examines the diverse use of visual representations by teachers in the science classroom. It contains unique pedagogies related to the use of visualization, presents original curriculum materials as well as explores future possibilities. The book begins by looking at the significance of visual representations in the teaching of science. It then goes on to detail two recent innovations in the field: simulations and slowmation, a process of explicit visualization. It also evaluates the way teachers have used different diagrams to illustrate concepts in biology and chemistry. Next, the book explores the use of visual representations in culturally diverse classrooms, including the implication of culture for teachers’ use of representations, the crucial importance of language in the design and use of visualizations, and visualizations in popular books about chemistry. It also shows the place of visualizations in the growing use of informal, self-directed science education. Overall, the book concludes that if the potential of visualizations in science education is to be realized in the future, the subject must be included in both pre-service and in-service teacher education. It explores ways to develop science teachers’ representational competence and details the impact that this will have on their teaching. The worldwide trend towards providing science education for all, coupled with the increased availability of color printing, access to personal computers and projection facilities, has lead to a more extensive and diverse use of visual representations in the classroom. This book offers unique insights into the relationship between visual representations and science education, making it an ideal resource for educators as well as researchers in science education, visualization and pedagogy
    Description / Table of Contents: Section A: Research into teaching with visual representationsIntroduction -- Chapter 1 : The significance of visual representations in the teaching of science, B. Eilam, J.K. Gilbert -- Chapter 2 : Teaching and researching visual representations: Shared vision or divided world? S. Ainsworth & L. Newton -- Section B: Teachers’ selections, constructions and use of visual representations -- Introduction -- Chapter 3 : Representing visually: What teachers know and what they prefer, B. Eilam, Y. Poyas, R. Hasimshoni -- Chapter 4 : Slowmation: A process of explicit visualisation, J. Loughran -- Chapter 5 : Secondary biology teachers’ use of different types of diagrams for different purposes, Y. Liu, M. Won, D.F. Treagust -- Chapter 6 : Teaching stoichiometry with particulate diagrams - linking macro phenomena and chemical equations, M.W. Cheng, J.K. Gilbert -- Section C: Teachers’ use of visual representations in culturally-diverse classrooms -- Introduction -- Chapter 7 : Thoughts on visualizations in diverse cultural settings: The case of France and Pakistan, E. De Vries, M. Ashraf -- Chapter 8 : The implication of culture for teachers’ use of representations, B. Waldrip, S. Satupo, F. Rodie -- Chapter 9 : The interplay between language and visualization: The role of the teacher, L. Mammino -- Chapter 10: Visualizations in popular books about chemistry, J.K. Gilbert, A. Afonso -- Section D: Teachers’ supporting student learning from visual representations -- Introduction -- Chapter 11 : Teachers using interactive simulations to scaffold inquiry instruction in physical science education, D. Geelan, X.Fan -- Chapter 12: Transformed instruction: Teaching in a student-generated representations learning environment, O. Parnafes, R. Trachtenberg-Maslaton -- Chapter 13: The laboratory for making things: Developing multiple representations of knowledge, J. Bamberger -- Section E: Overview -- Chapter 14: Developing science teachers’ representational competence and its impact on their teaching, J.K.Gilbert, B. Eilam.
    Note: Description based upon print version of record
    DOI: 10.1007/978-3-319-06526-7
    URL: Volltext
    URL: Volltext  (lizenzpflichtig)
    URL: Cover
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  • 2
    Online Resource
    Online Resource
    Science Education for Diversity : Theory and Practice (2013)
    Dordrecht : Springer
    Details
    ISBN: 9789400745636
    Language: English
    Pages: Online-Ressource (XX, 379 p. 46 illus, digital)
    Series Statement: Cultural Studies of Science Education 8
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Druckausg. Science education for diversity
    RVK:
    TB 4056
    Keywords: Science Study and teaching ; Religion and education ; Education ; Education ; Science Study and teaching ; Religion and education ; Pädagogische Soziologie
    Abstract: Reflecting the very latest theory on diversity issues in science education, including new dialogic approaches, this volume explores the subject from a range of perspectives and draws on studies from around the world. The work discusses fundamental topics such as how we conceptualize diversity as well as examining the ways in which heterogeneous cultural constructs influence the teaching and learning of science in a range of contexts. Including numerous strategies ready for adoption by interested teachers, the book addresses the varied cultural factors that influence engagement with science education. It seeks answers to the question of why increasing numbers of students fail to connect with science education in schools and looks at the more subtle impact that students’ individually constructed identities have on the teaching and learning of science. Recognizing the diversity of its audience, the book covers differing levels and science subjects, and examines material from a range of viewpoints that include pedagogy, curricula, teacher education, learning, gender, religion, and ICT, as well as those of in-service and trainee teachers at all levels
    Description / Table of Contents: Contents; Why Science Education for Diversity?; Introduction; What Do We Mean by Diversity?; Social and Historical Context; Cultural Diversity and Science Education; Sociocultural and Dialogic Perspectives; Tensions and Dilemmas; Argument and Structure of This Book; References; Part I: Science Education Reform for Diversity; Dialogic Science Education for Diversity; Introduction: The Science Education for Diversity Project; What Is Science?; Monologic, Dialogic and Diversity; How Do We Conceptualise Diversity?; Developing a Framework for Science Education for Diversity
    Description / Table of Contents: How Do We Make Science Education More Relevant?Will Inquiry-Based Science Education (IBSE) Help?; Explicitly Dialogic Pedagogy; Connecting to Real Science; Mastery Learning Combined with Dialogic Science Pedagogy; Teaching the Nature of Science; Teaching Thinking in Science and Through Science; The Role of ICT; The Need for Guided Collaborative Critical Reflection on Action; Summary and Conclusion; References; Expanding Notions of Scientific Literacy: A Reconceptualization of Aims of Science Education in the Knowledge Society
    Description / Table of Contents: The "Two Cultures" and the Need for a Broader Notion of Scientific LiteracyScientific Literacy Reconceptualized; Science Engagement Curriculum Policy Images; Science and the Public: An Online Graduate Program; The Inconvenient Truth: A Documentary on Global Warming; Oceanside Community Science Project (Roth and Lee 2004; Roth and Calabrese 2004); Conclusions; References; Activity, Subjectification, and Personality: Science Education from a Diversity-of-Life Perspective; Cultural-Historical Activity Theory; Activity and Actions; Subjectification; Personality; On the Way to Become a Doctor
    Description / Table of Contents: Early Activities and RelationsHigh School Science; Science Internship; College Science; Resident Care Assistant; Coda; References; Reflexivity and Diversity in Science Education Research in Europe: Towards Cultural Perspectives; Introduction; Cultural Studies and Issues of Diversity in Science Education; The State of the Art of Cultural Studies of Science Education in Europe; Reflexivity: Theoretical Barriers and Horizons; Towards Cultural Studies as a Unifying Research Paradigm; References; Part II: From Learning to Pedagogy; Science Education for Diversity and Informal Learning
    Description / Table of Contents: Importance of Informal Environments for Learning ScienceKey Features of Science Learning in Informal Environments; Activation of Prior Knowledge; Acknowledging and Valuing Multiple Perspectives; Sociocultural Frameworks for Informal Science Learning; Sociocultural Approach with Individual Science Learning Goals: Social Constructivism; Sociocultural Approach with Community Learning Goals: Collective Praxis; The Practice of Informal Science Education for Diversity; Examples of the Impact of Exhibit Design on Collaborative Talk; Involving Diverse Groups in Development of Programs and Exhibits
    Description / Table of Contents: Step 1
    Description / Table of Contents: Introduction -- Why science education for diversity? Nasser Mansour and Rupert Wegerif -- Part 1. Science education reform for diversity -- Chapter 1: Dialogic Science Education for Diversity, Rupert Wegerif, Keith Postlethwaite, Nigel Skinner, Nasser Mansour, Alun Morgan, Lindsay Hetherington -- Chapter2: Expanding Notions of Scientific Literacy: A Re-conceptualization of Aims of Science Education in the Knowledge Society, Xiufeng Liu -- Chapter3: Activity, Subjectification, and Personality: Science Education from a Diversity-of-Life Perspective, Wolff-Michael Roth, University of Victoria -- Chapter 4: Reflexivity and diversity in research on science education: A European account, Michiel van Eijck -- Part 2, from learning to pedagogy -- Chapter 5: Science education for diversity and informal learning, Loran E. Parker and Gerald H. Krockover -- Chapter 6: Diverse, disengaged and reactive: A teacher’s adaptation of ethical dilemma story pedagogy as a strategy to re-engage learners in education for sustainability,  Elisabeth Taylor, Peter Charles Taylor and MeiLing Chow -- Chapter 7: Tracing science in the early childhood classroom: the historicity of multi-resourced discourse practices in multilingual interaction, Charles Max, Gudrun Ziegler and Martin Kracheel -- Chapter 8: Conceptual frameworks, metaphysical commitments and worldviews: the challenge of reflecting the relationships between science and religion in science education, Keith S. Taber -- Chapter 9: Science Curriculum Reform on “Scientific Literacy for All” across National Contexts: Case Studies of Curricula from England and Hong Kong, Sibel Erduran and Siu Ling Wong -- Part 3 science teacher Education and diversity -- Chapter 10: Science teachers' cultural beliefs and diversities: A sociocultural perspective to science education, Nasser Mansour -- Chapter 11: Envisioning Science Teacher Preparation for Diversity in 21st Century Classrooms: Some Tensions, Norm Thomson, Deborah J. Tippins -- Chapter12: Expanded agency in multilingual science teacher training classrooms, Silvia Lizette Ramos De Robles & Mariona Espinet -- Part 4  Cultural issues in science Education -- Chapter 13: Re-conceptualizing a lifelong science education system that supports diversity: The role of free-choice learning, Lynn D. Dierking -- Chapter 14: Ignoring half the Sky: A feminist critique of science education’s knowledge society, Kathryn Scantlebury, Anita Hussénius, Kristina Andersson and Annica Gullberg -- Chapter 15: Religion in Science Education, Michael J. Reiss -- Chapter 16: Students’ perceptions of apparent contradictions between science and religion: Creation is only the beginning, Berry Billingsley -- Chapter 17: Gender and science in the Arab states: Current status and future prospects, Saouma BouJaoude & Ghada Gholam.
    Note: Description based upon print version of record
    DOI: 10.1007/978-94-007-4563-6
    URL: Volltext
    URL: Volltext  (lizenzpflichtig)
    URL: Cover
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  • 3
    Online Resource
    Online Resource
    Science Education Research and Practice in Europe : Retrosspective and Prospecctive (2012)
    Rotterdam : SensePublishers
    Details
    ISBN: 9789460919008
    Language: English
    Pages: Online-Ressource (VIII, 394 p, digital)
    Series Statement: Cultural Perpectives in Science Education 5
    Series Statement: Cultural and Historical Perspectives on Science Education 13/5
    Series Statement: Educational Research E-Books Online, Collection 2005-2017, ISBN: 9789004394001
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Erscheint auch als Science Education Research and Practice in Europe: Retrospective and Prospective
    RVK:
    TB 4056
    RVK:
    DP 4600
    Keywords: Science Study and teaching ; Education ; Education
    Abstract: Preliminary Material /Doris Jorde and Justin Dillon -- Science Education Research and Practice in Europe: Retrospective and Prospective /Doris Jorde and Justin Dillon -- The Model of Educational Reconstruction – A Framework for Improving Teaching and Learning Science /Reinders Duit , Harald Gropengießer , Ulrich Kattmann , Michael Komorek and Ilka Parchmann -- Transcending Science: Scientific Literacy and Bildung for the 21st Century /Per-Olof Wickman , Caroline Liberg and Leif Östman -- How Research on Students’ Processes of Concept Formation can Inform Curriculum Development /Claudia V. Aufschnaiter and Christian Rogge -- Studies of the Development of Students’ Understandings of Ecological Phenomena /Gustav Helldén -- Video Analysis as a tool for Understanding Science Instruction /Hans E. Fischer and Knut Neumann -- The Nature of Video Studies in Science Education /Andrée Tiberghien and Gérard Sensevy -- Teaching Activities and Language use in Science Classrooms /Marianne Ødegaard and Kirsti Klette -- Results and Perspectives from the ROSE Project /Svein Sjøberg and Camilla Schreiner -- The Cultural Context of Science Education /Cathrine Hasse and Anne B. Sinding -- Argumentation in Science Education Research: Perspectives from Europe /Sibel Erduran and Maria Pilar Jiménez-Aleixandre -- Classroom Discourse and Science Learning: Issues of Engagement, Quality and Outcome /Asma Almahrouqi and Phil Scott -- School Health Education Nowadays: Challenges and Trends /Graça S. Carvalho and Dominique Berger -- Science Education Research in Turkey: A Content Analysis of Selected Features of Published Papers /Mustafa Sozbilir , Hulya Kutu and M. Diyaddin Yasar -- Improving Science Education Through European Models of Sustainable Teacher Professional Development /Matthias Stadler and Doris Jorde.
    Abstract: Each volume in the 7-volume series The World of Science Education reviews research in a key region of the world. These regions include North America, South and Latin America, Asia, Australia and New Zealand, Europe, Arab States, and Sub-Saharan Africa. The focus of this Handbook is on science education in Europe. In producing this volume the editors have invited a range of authors to describe their research in the context of developments in the continent and further afield. In reading this book you are invited to consider the historical, social and political contexts that have driven developments in science education research over the years. A unique feature of science education in Europe is the impact of the European Union on research and development over many years. A growing number of multi-national projects have contributed to the establishment of a community of researchers increasingly accepting of methodological diversity. That is not to say that Europe is moving towards homogeneity, as this volume clearly shows
    Description / Table of Contents: ""Science Education Research and Practice in Europe""; ""ACKNOWLEDGEMENTS""; ""CONTENTS""; ""1. SCIENCE EDUCATION RESEARCH AND PRACTICEIN EUROPE: RETROSPECTIVE AND PROSPECTIVE""; ""INTRODUCTION""; ""WHAT COUNTS AS EUROPE?""; ""A RETROSPECTIVE LOOK AT SCIENCE EDUCATION IN EUROPE""; ""England: An Example of the Development of Science Education in Europe""; ""RESEARCH IN SCIENCE EDUCATION IN EUROPE""; ""POLICY TEXTS AND THE NATURE OF SCIENCE EDUCATION""; ""SCIENCE EDUCATION RESEARCH AND DEVELOPMENT IN THE EU""; ""REFERENCES""; ""AFFILIATIONS""
    Description / Table of Contents: ""2. THE MODEL OF EDUCATIONAL RECONSTRUCTION � A FRAMEWORK FOR IMPROVING TEACHING AND LEARNING SCIENCE""""OVERVIEW""; ""ON THE INTERRDISCIPLINARRY NATURE OFF SCIENCE EDDUCATION""; ""TRADITIONS OF SCIENCE EDUCATION RESEARCH""; ""THE GERMAN TRADITION OF BILDUNG AND DIDAKTIK""; ""THE MODEL OF EDUCATIONAL RECONSTRUCTION""; ""Introductory Remarks""; ""Epistemological Orientation""; ""Overview of the Model""; ""Component (1): Clarification and Analysis of Science Content""; ""Component (2): Research on Teaching and Learning""
    Description / Table of Contents: ""Component (3): Design and Evaluation of Teaching and Learning Environments""""The Recursive Process of Educational Reconstruction""; ""The Model of Educational Reconstruction and Other Models of Instructional Design""; ""CONCLUSIONS � ON THE ROLE OF THE MODEL OF EDUCATIONAL""; ""The Model of Educational Reconstruction as a Framework for Science Education Research""; ""Conceptual Reconstruction""; ""The Model of Educational Reconstruction as a Model for Teacher Professional Development""; ""The Model of Educational Reconstruction for Teacher Education""; ""CODA""; ""NOTES""; ""REFERENCES""
    Description / Table of Contents: ""AFFILIATIONS""""3. TRANSCENDING SCIENCE: SCIENTIFIC LITERACY AND BILDUNG FOR THE 21ST CENTURY ""; ""OVERVIEW""; ""INTRODUCTION""; ""Bildung""; ""Vision 1 and Vision 2""; ""Transcending Science""; ""THE DIMENSION OF NORMATIVITY""; ""Moral/ethical""; ""Political""; ""Norms""; ""Aesthetics""; ""Transformation""; ""TEACHING AND LEARNING SCIENCE AS ACTION""; ""Situating Science in an Activity""; ""The Quest for Relevant Activities""; ""A Pragmatist Interpretation""; ""Developing Science Activities""; ""LANGUAGE AND SCIENCE EDUCATION""; ""Modes of Communication""; ""Language Dimensions""
    Description / Table of Contents: ""CONCLUDING REMARKS""""ACKNOWLEDGEMENTS""; ""REFERENCES""; ""4. HOW RESEARCH ON STUDENTS� PROCESSES OF CONCEPT FORMATION CAN INFORM CURRICULUM DEVELOPMENT""; ""ABSTRACT""; ""INTRODUCTION""; ""A BRIEF CRITICAL DISCUSSION OF RESEARCH ON CONCEPTUAL CHANGE""; ""Theoretical Descriptions of Concepts and Conceptual Change""; ""Concepts""; ""Conceptual Change""; ""Empirical Approaches towards Investigating Conceptual Change""; ""CONCLUSIONS""; ""SAMPLE, PROCEDURES, AND METHODS""; ""Procedures and Samples""; ""Methods""; ""EMPIRICAL RESULTS ON STUDENTS� PROCESSES OF CONCEPT FORMATION""
    Description / Table of Contents: ""Conceptual Qualities""
    Note: Includes bibliographical references
    DOI: 10.1007/978-94-6091-900-8
    URL: Volltext  (lizenzpflichtig)
    URL: Volltext  (lizenzpflichtig)
    URL: Cover
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  • 4
    Online Resource
    Online Resource
    The Invention of Science : Why History of Science Matters for the Classroom (2011)
    Rotterdam : SensePublishers
    Details
    ISBN: 9789460915253
    Language: English
    Pages: Online-Ressource (X, 181p, digital)
    Series Statement: Cultural Perspectives in Science Education: Research Dialogs 4
    Series Statement: Educational Research E-Books Online, Collection 2005-2017, ISBN: 9789004394001
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Buchausg. u.d.T.
    DDC: 509
    RVK:
    TB 2300
    Keywords: Education ; Science History ; Study and teaching ; Science Study and teaching ; Science Study and teaching ; Education
    Abstract: Preliminary Material -- What is Science? -- Making Arguments -- Warring Cosmologies and the Emergence of Eurocentric Science -- Valuing Patterns and the Continuing Emergence of Eurocentric Science -- Just the Facts, Please -- Understanding and Explanation -- Understanding Discourses in Science and Science Education -- Final Comments.
    Abstract: The Invention of Science: Why History of Science Matters for the Classroom introduces readers to some of the developments that were key for the emergence of Eurocentric science, the discipline we call science. Using history this book explores how human groups and individuals were key to the invention of the discipline of we call science. All human groups have a need and desire to produce systematic knowledge that supports their ongoing survival as a community. This book examines how history can help us to understand emergence of Eurocentric science from local forms of systematic knowledge. Each chapter explores elements that were central to the invention of science including beliefs of what was real and true, forms of reasoning to be valued, and how the right knowledge should be constructed and the role of language. But most importantly this book presented these ideas in an accessible way with activities and questions to help readers grapple with the ideas being presented. Enjoy!
    Description / Table of Contents: The Invention of Science; TABLE OF CONTENTS; PREFACE; HISTORIOGRAPHY; Theoretical Lens; Great men change history.; Historical forces.; How societies/civilizations respond to a crisis of ideas or technology determines whether they will survive.; Dialectical argument.; Geography determines the character of people and gives them advantages and disadvantages.; The outcome of ideas and practices coming together and their effect cannot be predicted.; The relationship between history and the writing of history is ambiguous.; THE NEED FOR A HISTORY OF SCIENCE; NOTES; CHAPTER 1: WHAT IS SCIENCE?
    Description / Table of Contents: Activity: What is science?TAKING A DIFFERENT VIEW; SCIENCE, EUROCENTRIC SCIENCE (ES), AND INDIGENOUS KNOWLEDGE (IK); Universal and Pluralist Models of Science in Science Education; Question.; Activity; Activity; SO WHAT IS SYSTEMATIC KNOWLEDGE AND WHAT ARE THE ORIGINS OF SCIENCE?; Emerging Systematic Knowledge; NOTES; CHAPTER 2: MAKING ARGUMENTS; Activity; WHAT KNOWLEDGE IS OF MOST WORTH: THE PHILOSOPHIES OF PLATO AND ARISTOTLE; Politics; best regulated states will not permit a mechanic to be a citizen; ; practical,; theoretical; productive; Reasoning and Logic; Dialectical reasoning.
    Description / Table of Contents: Analogical reasoning.Deductive reasoning.; Inductive reasoning.; Abductive reasoning.; Pierce's model for abduction.; Activity; Story 1.; Story 2.; Story 3.; Story 4.; Teleology and the Idea of Causes; Activity; Aristotle's Universe; Activity; The earth.; The heavens.; How we understand things.; Motion.; Activity; Causation.; Activity; Activity; Living things.; NOTES; CHAPTER 3: WARRING COSMOLOGIES AND THE EMERGENCE OF EUROCENTRIC SCIENCE; GALEN'S OBSERVATIONS; ARISTOTELIANISM AS A WORLDVIEW IN MEDIEVAL EUROPE; WHAT IS A WORLDVIEW?; Activity; Activity; Question.
    Description / Table of Contents: THIS IS ALL VERY WELL BUT HOW DOES THIS AFFECT MY SCIENCE TEACHING?ARISTOTELIANISM AND MECHANISM; Activity; VIOLENT MOTION; A Specific Example - On Motion; Activity; Activity; RENE DÉSCARTES AND MECHANISM; Activity; AND THE EXPERIMENTAL PHILOSOPHERS; Question.; Activity; Activity; The Machine Metaphor and Experiments; Worldview and Questions; Activity.; NOTES; CHAPTER 4: VALUING PATTERNS AND THE CONTINUING EMERGENCE OF EUROCENTRIC SCIENCE; Activity; EXPLORING THE WORLD: THE RISE OF NATURAL HISTORY; THEOLOGICAL VOLUNTARISM VERSUS INTELLECTUALISM; OTHER DEVELOPMENTS; Activity
    Description / Table of Contents: Other aspects of Arabic science.The emergence of friar organizations.; Moveable type and the printing press.; On the Workings of the Human Body; The use of vernacular language.; Question.; Activity; THE EMERGENCE OF EUROCENTRIC SCIENCE; LOOKING FOR PATTERNS: SOME OBSERVATIONS AND DEVELOPMENTS; The Beginnings of a New Worldview; Activity; Considering the Theoretical Possibilities; Filoteo.; USING PHYSICAL MODELS SUPPORTING A DIFFERENT WORLDVIEW; Activity; DISRUPTING PATTERNS IN THE SKY: A FURTHER CHALLENGE TO ARISTOTLEIANISM?; Activity; WHAT IS A LAW, SCIENTIFICALLY?
    Description / Table of Contents: Activity - So What is Needed for a Law? Seeing Patterns in the Data
    Note: Description based upon print version of record
    DOI: 10.1007/978-94-6091-525-3
    URL: Volltext  (lizenzpflichtig)
    URL: Volltext  (lizenzpflichtig)
    URL: Volltext
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