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  • MPI Ethno. Forsch.  (12)
  • Education  (12)
  • Monografische Reihe
  • Physics  (12)
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  • MPI Ethno. Forsch.  (12)
  • BSZ  (6)
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  • 1
    Online Resource
    Online Resource
    Wissenschaftliche Kontroversen im Physikunterricht : Explorationsstudie zum Umgang von Physiklehrkräften und Physiklehramtsstudierenden mit einer wissenschaftlichen Kontroverse am Beispiel der Masse in der Speziellen Relativitätstheorie (Volume 333) (2022)
    [Erscheinungsort nicht ermittelbar] : Logos Verlag Berlin
    Details
    ISBN: 9783832554781
    Language: Undetermined
    Pages: 1 Online-Ressource
    RVK:
    UB 4052
    Keywords: Education ; Physics ; Masse ; Spezielle Relativitätstheorie ; Kontroverse ; Physikunterricht ; Physiklehrer ; Physiklehrerin ; Lehramtsstudent ; Lehramtsstudentin ; Studie
    Abstract: Erkenntnisgewinnung ist in den Naturwissenschaften untrennbar mit wissenschaftlichen Kontroversen verknüpft, die auch für den Physikunterricht einen Bildungswert besitzen, insbesondere im Hinblick auf kritische Urteilsbildung, Multiperspektivität und ein angemessenes Nature-of-Science-Verständnis. Basierend auf einer Charakterisierung wissenschaftlicher Kontroversen wird am Beispiel der Frage nach der Relativität der Masse in der Speziellen Relativitätstheorie in einer explorativ-qualitativen Studie untersucht, wie Physiklehrkräfte und Physiklehramtsstudierende mit einer solchen Kontroverse umgehen und inwieweit sie deren Bildungswert nutzen. Dazu werden sowohl Gedankenauflistungen, die von den Befragten nach dem Lesen von Textmaterialien zu den unterschiedlichen Fachpositionen erstellt wurden, als auch Antworten zu verschiedenen Textvignetten mit Hilfe der qualitativen Inhaltsanalyse ausgewertet. Insgesamt zeigt sich, dass die Studierenden häufiger offen gegenüber den kontroversen fachwissenschaftlichen Positionen sind als die Lehrkräfte. Unterschiede in Bezug auf die Realisierung des Bildungswertes im Unterrichtskontext werden mithilfe von fünf Typen systematisch beschrieben. Ein Großteil der Befragten weist dabei Ansätze zur Umsetzung von Kontroversität im Physikunterricht auf. Die Mehrheit vertritt auch eine eigene fachwissenschaftliche Position und ein Teil der Befragten nutzt die wissenschaftliche Kontroverse zur Thematisierung von Nature-of-Science-Aspekten.
    Note: German
    URL: kostenfrei
    URL: https://www.logos-verlag.de/cgi-bin/engbuchmid?isbn=5478&lng=deu&id=
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  • 2
    Online Resource
    Online Resource
    Pädagogik der Naturwissenschaften : ein Studienbuch (2017)
    Wiesbaden : Springer VS
    Details
    ISBN: 9783531195469
    Language: German
    Pages: 1 Online-Ressource (VII, 248 Seiten) , Illustrationen
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Erscheint auch als Gebhard, Ulrich, 1951 - Pädagogik der Naturwissenschaften
    RVK:
    TB 4056
    RVK:
    UB 4056
    RVK:
    VB 4045
    RVK:
    WB 4049
    Keywords: Teaching ; Education ; Education ; Teaching ; Education ; Teaching ; Teaching and Teacher Education ; Naturwissenschaftlicher Unterricht ; Physikunterricht ; Chemieunterricht ; Biologieunterricht ; Naturwissenschaftlicher Unterricht ; Physikunterricht ; Chemieunterricht ; Biologieunterricht
    Abstract: Eine „Pädagogik der Naturwissenschaften“ fragt einerseits nach gelingendem Lernen und andererseits nach gelingender Bildung mit und durch die Naturwissenschaften. Wenn Lernen und Bildung gelingen sollen, dann wird sich die fachdidaktische Aufmerksamkeit sowohl auf das Subjekt als auch auf das Objekt von Lernen und Bildung im naturwissenschaftlichen Fachunterricht richten müssen. In der Verschränkung von Subjektivierung und Objektivierung sehen wir den fruchtbaren Moment naturwissenschaftlicher Bildungsprozesse, die damit eine gleichermaßen pädagogische wie politische Dimension erhalten. In diesem Buch werden die wesentlichen, theoretisch gehaltvollen Elemente einer kritischen wie modernen Naturwissenschaftsdidaktik diskutiert. Die Lektüre des Buches soll die pädagogisch-didaktische Haltung von Fachdidaktikerinnen und Fachdidaktikern, Studierenden und Lehrkräften inspirieren und theoretisch unterfüttern. Daher akzentuieren wir wesentliche Prämissen, theoretische Grundlegungen und Ziele des naturwissenschaftlichen Unterrichts. Zentrale Problemstellungen einer „Pädagogik der Naturwissenschaften“ werden aus einer integrativen Perspektive bearbeitet. Dabei werden sowohl Bezüge zum disziplinären Physik-, Chemie- und Biologieunterricht als auch zu einem integrierten Fach Naturwissenschaft hergestellt. Ein klarer Theoriebezug steht dabei in einem ausgewogenen Verhältnis zu empirischen Forschungsbefunden und zu Praxisempfehlungen. Die Autoren Dr. Ulrich Gebhard ist Professor für Erziehungswissenschaft unter besonderer Berücksichtigung der Didaktik der Biowissenschaften an der Universität Hamburg. Dr. Dietmar Höttecke ist Professor für Didaktik der Erziehungswissenschaften unter besonderer Berücksichtigung der Didaktik der Physik an der Universität Hamburg. Dr. Markus Rehm ist Professor für Didaktik der Naturwissenschaften an der Pädagogischen Hochschule Heidelberg
    Abstract: Einführung -- Was ist Naturwissenschaft?- Bildungstheoretische Grundlegung -- Naturwissenschaft, Ideologie, Unterricht -- Bildungsstandards und Kompetenzorientierung -- Naturwissenschaftlicher Unterricht -- Alltag und Wissenschaft -- Sprache, Begriff, Denken -- Natur und Naturbeziehung -- Urteilen, Entscheiden, Kommunizieren -- Lernen über die Natur der Naturwissenschaft -- Naturwissenschaften lernen, Naturwissenschaften verstehen -- Vom gefächerten zum integrierten Unterricht
    DOI: 10.1007/978-3-531-19546-9
    URL: Volltext
    URL: Volltext  (lizenzpflichtig)
    URL: Cover
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  • 3
    Online Resource
    Online Resource
    Naturwissenschaftliche Bildung in der Migrationsgesellschaft : Grundzüge einer Reflexiven Physikdidaktik und kritisch-sprachbewussten Praxis (2017)
    Wiesbaden : Springer VS
    Details
    ISBN: 9783658171230
    Language: German
    Pages: Online-Ressource (XXVI, 410 S. 41 Abb, online resource)
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Druckausg.
    Parallel Title: Erscheint auch als Tajmel, Tanja ISBN Naturwissenschaftliche Bildung in der Migrationsgesellschaft
    RVK:
    DP 4600
    RVK:
    DO 9000
    RVK:
    UB 4056
    Keywords: Language and education ; Science education ; Educational sociology ; Education and sociology ; Sociology, Educational ; Education ; Education ; Language and education ; Science education ; Educational sociology ; Education and sociology ; Sociology, Educational ; Hochschulschrift ; Physikunterricht ; Einwanderer ; Fremdsprachenlernen
    Abstract: Tanja Tajmel entwickelt eine intersektionale Perspektive auf naturwissenschaftliche Bildung und Physikunterricht im Kontext von Migration und Mehrsprachigkeit. Ausgehend vom Recht auf Bildung und unter Einbeziehung sozial- und sprachwissenschaftlicher Ansätze argumentiert die Autorin analytisch-theoriebildend die Grundzüge einer ‚Reflexiven Physikdidaktik‘, deren Anliegen ein diskriminierungsfreier Zugang zu Bildung ist. Mit der Modellierung einer ‚kritisch-reflexiven Sprachbewusstheit‘ legt die Autorin die Grundlage für eine reflexive Praxis der schulischen Sprachbildung, die sie an Beispielen exploriert. Der Inhalt Disparitäten der naturwissenschaftlichen Bildung als soziale Ungleichheit Diversität, Differenz und Macht in der physikdidaktischen Forschung Fachkultur und Sprache als Barrieren des Bildungszugangs Deutsch als Zweitsprache und Critical Language Awareness Kritische Sprachbewusstheit als reflexive Professionalität Die Zielgruppen Dozierende und Studierende des Lehramts, insbesondere naturwissenschaftlicher Fächer, sowie der Bereiche Sprachbildung und Deutsch als Zweitsprache Praktikerinnen und Praktiker im Bereich Schule sowie in der Aus- und Fortbildung von Lehrkräften Die AutorinTanja Tajmel promovierte im Fachbereich Didaktik der Physik an der Humboldt-Universität zu Berlin und ist Dozentin für Deutsch als Zweitsprache. Zu ihren Forschungsschwerpunkten zählen Sprache im Fachunterricht und Diskriminierung im Zugang zu naturwissenschaftlicher Bildung
    Abstract: Disparitäten der naturwissenschaftlichen Bildung als soziale Ungleichheit -- Diversität, Differenz und Macht in der physikdidaktischen Forschung -- Fachkultur und Sprache als Barrieren des Bildungszugangs -- Deutsch als Zweitsprache und Critical Language Awareness -- Kritische Sprachbewusstheit als reflexive Professionalität
    Note: Literaturverzeichnis: Seite 385-431
    DOI: 10.1007/978-3-658-17123-0
    URL: Volltext
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  • 4
    Online Resource
    Online Resource
    Philosophie und Physik am außerschulischen Lernort : Konzepte zur Natur der Naturwissenschaften an Schule und Hochschule (2016)
    Wiesbaden : Springer Spektrum
    Details
    ISBN: 9783658118518
    Language: German
    Pages: 1 Online-Ressource (IX, 43 Seiten) , Illustrationen
    Series Statement: essentials
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Erscheint auch als Haardiek, Annika, 1985 - Philosophie und Physik am außerschulischen Lernort
    RVK:
    UB 4060
    Keywords: Education ; Philosophy and science ; Science education ; Physics ; Education ; Philosophy and science ; Science education ; Physics
    Abstract: Dieses essential zeigt am Beispiel des innovativen Projekts „Selberdenken!“ auf, wie eine Verbindung von Naturwissenschaft und Philosophie auf der Basis von forschend-entdeckendem Lernen und explorativem Experimentieren an Schule und Hochschule gelingt. Fragen wie „Was denkt man, wenn man nach den Bausteinen der Materie sucht?“ und „Wie schafft man es, Daten durch die Luft zu transportieren?“ bieten dabei das Potenzial, Jugendliche für ein tiefgreifendes Verständnis unserer technisierten Welt zu begeistern. Motor für diese kritisch-neugierige Perspektive ist die Naturphilosophie, die auf lebendige Weise neben der fachlichen Dimension auch die Hintergründe von Naturwissenschaft thematisiert. Der Inhalt Ansichten über die Natur der Naturwissenschaften Grundlagen der Naturphilosophie „Selberdenken!“ – Ein Projektkurs am außerschulischen Lernort Die Zielgruppen Studierende und Dozierende der Lehramtsstudiengänge, insbesondere der Naturwissenschaften und der Philosophie Lehrende und Dozierende an Schulen und Hochschulen, Pädagogen Die Autorinnen Annika Kruse, M.Sc. Physik, promoviert am Schülerlabor MExLab Physik in Münster und ist dort für die Koordination sowie die Entwicklung des Workshopangebots zuständig. Cornelia Denz ist Professorin am Institut für Angewandte Physik der Westfälischen Wilhelms-Universität Münster (WWU). Sie ist Leiterin des Schülerlabors MExLab Physik sowie Prorektorin für Internation ales und wissenschaftlichen Nachwuchs an der WWU. .
    Description / Table of Contents: Was Sie in diesem Essential finden können; Vorwort ; Inhaltsverzeichnis; Kapitel-1; Einleitung; Literatur; Kapitel-2; Ansichten über die Natur der Naturwissenschaften; 2.1 Analyse der Misskonzepte über die Natur der Naturwissenschaften bei Jugendlichen; 2.2 Allgemeine Charakteristika eines Unterrichts zur Natur der Naturwissenschaft; Literatur; Kapitel-3; Grundzüge und Anwendung der Naturphilosophie; 3.1 Wissenschaftstheorie und die Naturwissenschaften; 3.2 Naturphilosophie und Physikdidaktik; Literatur; Kapitel-4; Selberdenken! - Ein Workshopkonzept am außerschulischen Lernort
    Description / Table of Contents: 4.1 Perspektiven an Schülerlaboren4.2 Der Projektkurs „Selberdenken!"; 4.3 Themen für ein Projekt zur Naturphilosophie; 4.4 Detaillierte Workshopbeispiele aus Selberdenken; Literatur; Kapitel-5; Fazit und Ausblick; Was Sie aus diesem Essential mitnehmen können
    Note: Description based upon print version of record
    DOI: 10.1007/978-3-658-11851-8
    URL: Volltext  (lizenzpflichtig)
    URL: Volltext  (lizenzpflichtig)
    URL: Cover
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  • 5
    Online Resource
    Online Resource
    Teaching and Learning of Energy in K – 12 Education (2014)
    Cham : Springer International Publishing
    Details
    ISBN: 9783319050171
    Language: English
    Pages: Online-Ressource (IX, 379 p. 35 illus., 16 illus. in color, online resource)
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Druckausg. Teaching and learning of energy in K-12 education
    RVK:
    UB 4049
    RVK:
    DV 2850
    RVK:
    ZP 2700
    Keywords: Science Study and teaching ; Education ; Education ; Science Study and teaching ; Force and energy Study and teaching ; Power (Mechanics) Study and teaching ; Power resources Study and teaching ; Science Study and teaching (Elementary) ; Konferenzschrift 2013 ; Energie ; Unterricht
    Abstract: This volume presents current thoughts, research, and findings that were presented at a summit focusing on energy as a cross-cutting concept in education, involving scientists, science education researchers and science educators from across the world. The chapters cover four key questions: what should students know about energy, what can we learn from research on teaching and learning about energy, what are the challenges we are currently facing in teaching students this knowledge, and what needs be done to meet these challenges in the future? Energy is one of the most important ideas in all of science and it is useful for predicting and explaining phenomena within every scientific discipline. The challenge for teachers is to respond to recent policies requiring them to teach not only about energy as a disciplinary idea but also about energy as an analytical framework that cuts across disciplines. Teaching energy as a crosscutting concept can equip a new generation of scientists and engineers to think about the latest cross-disciplinary problems, and it requires a new approach to the idea of energy. This book examines the latest challenges of K-12 teaching about energy, including how a comprehensive understanding of energy can be developed. The authors present innovative strategies for learning and teaching about energy, revealing overlapping and diverging views from scientists and science educators. The reader will discover investigations into the learning progression of energy, how understanding of energy can be examined, and proposals for future directions for work in this arena. Science teachers and educators, science education researchers and scientists themselves will all find the discussions and research presented in this book engaging and informative.
    Description / Table of Contents: Acknowledgements; Contents; Chapter 1: Introduction: Why Focus on Energy Instruction?; 1.1 Realizing the Need for a Summit; 1.2 Structure of the Summit; 1.2.1 Goals and Participants; 1.2.2 Surfacing and Discussing Ideas; 1.2.3 Teacher Voices and a Second Summit for Teachers; 1.3 Organization of This Book; References; Part I What Should Students Know About Energy?; Chapter 2: A Physicist's Musings on Teaching About Energy; 2.1 Introduction; 2.2 The Particle Physicist's View of Energy; 2.3 Descriptions of Various Types of Energy; 2.3.1 Thermal Energy; 2.3.2 Chemical Energy
    Description / Table of Contents: 2.3.3 Mechanical and Electrical Energy2.3.4 Conservation of Mass?; 2.3.5 Energy Flows (Convection, Conduction and Radiation); 2.3.6 Nuclear Energy; 2.4 Key Energy Concepts for K-12 Science Education; 2.4.1 Only Changes in Energy Matter (Who Cares How Much You Have if Most of It Is Not Negotiable); 2.4.2 Any Change in Energy Is Balanced by Some Other Change in Energy (You Can't Make or Destroy Energy, Only Move It Around); 2.4.3 Energy Availability Governs What Can Happen (You Can't Do Anything Without Energy); 2.4.4 Energy Tends to Spread Itself Around as Much as Possible
    Description / Table of Contents: 2.5 When and How Can Students Learn About Energy?References; Chapter 3: A Space Physicist's Perspective on Energy Transformations and Some Implications for Teaching About Energy Conservation at All Levels; 3.1 Introduction; 3.2 Magnetic Reconnection: Energy in Fields; 3.3 The Energy Transport Equation in Magnetohydrodyamics: Energy Conservation and Transfer; 3.4 Conclusions; References; Chapter 4: Conservation of Energy: An Analytical Tool for Student Accounts of Carbon-Transforming Processes; 4.1 Introduction; 4.2 A Key Goal: Using Energy Conservation as an Analytical Tool
    Description / Table of Contents: 4.3 Challenges and Instructional Supports4.3.1 Understanding the Purpose of the Concept of Energy; 4.3.1.1 Developing a Sense of Necessity About Energy Conservation; 4.3.1.2 Quasi-quantitative Representations of Energy; 4.3.2 Identifying Forms of Energy in Living Systems; 4.3.3 Tracing Energy Separately from Matter; 4.4 Conclusion; References; Part II What Does the Research Say About the Teaching and Learning About Energy?; Chapter 5: Teaching and Learning the Physics Energy Concept; 5.1 Introduction; 5.2 Energy - A Core Physics Concept; 5.2.1 On the Energy Concept in Physics
    Description / Table of Contents: 5.2.2 Four Basic Ideas of the Energy Concept5.2.3 On the Nature of the Four Basic Ideas; 5.2.4 On the Relation of the Four Basic Ideas to Standards and Instruction; 5.3 Conceptualizations of Energy; 5.3.1 Energy Is an Abstract Accounting Quantity; 5.3.2 Energy Is the Ability to Do Work; 5.3.3 Energy Is the Ability to Cause Changes; 5.3.4 Energy Is the Ability to Produce Heat; 5.3.5 Energy Is a General Kind of Fuel; 5.3.6 The Conceptualist and the Materialist Distinction; 5.3.7 Energy Is a Substance-Like Quantity; 5.3.8 Energy Forms; 5.4 Findings of Studies on Teaching and Learning Energy
    Description / Table of Contents: 5.4.1 On the State of Research in the Early 1990s
    Note: Description based upon print version of record
    DOI: 10.1007/978-3-319-05017-1
    URL: Volltext
    URL: Volltext
    URL: Cover
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  • 6
    Online Resource
    Online Resource
    Modeling Students' Mathematical Modeling Competencies : ICTMA 13 (2013)
    Dordrecht : Springer Netherlands
    Details
    ISBN: 9789400762718
    Language: English
    Pages: Online-Ressource (XIV, 651 p. 134 illus, digital)
    Series Statement: International Perspectives on the Teaching and Learning of Mathematical Modelling
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Buchausg. u.d.T.
    RVK:
    DP 4600
    RVK:
    SM 630
    RVK:
    TB 4053
    RVK:
    UB 4049
    RVK:
    VB 4052
    Keywords: Mathematics ; Education ; Education ; Mathematics
    Abstract: Modeling Students Mathematical Modeling Competencies offers welcome clarity and focus to the international research and professional community in mathematics, science, and engineering education, as well as those involved in the sciences of teaching and learning these subjects.
    Abstract: Modeling Students' Mathematical Modeling Competencies offers welcome clarity and focus to the international research and professional community in mathematics, science, and engineering education, as well as those involved in the sciences of teaching and learning these subjects
    Description / Table of Contents: Modeling Students' Mathematical Modeling Competencies; Contents; Contributors; Chapter 1: Introduction: ICTMA and the Teaching of Modeling and Applications; Part I: The Nature of Models & Modeling; Chapter 2: Introduction to Part I Modeling: What Is It? Why Do It?; References; Section 1: What Are Models?; Chapter 3: Modeling Theory for Math and Science Education; 3.1 Introduction; 3.2 Origins of Modeling Theory; 3.3 Models and Concepts; 3.4 Imagination and Intuition; 3.5 Mathematical Versus Physical Intuition; 3.6 Modeling Instruction; 3.7 Conclusions
    Description / Table of Contents: 3.8 Epilogue: A New Generation of Mathematical ToolsReferences; Chapter 4: Modeling a Crucial Aspect of Students' Mathematical Modeling; 4.1 Introduction; 4.2 Three Examples; 4.3 The Intricacies of Mathematization; 4.4 Modeling Students' Mathematizations; References; Chapter 5: Modeling Perspectives in Math Education Research; 5.1 Introduction; 5.2 Spesier and Walter on Models; 5.3 Harel on Models; 5.4 Larson on Models; 5.5 Oehrtman on Models; 5.6 Rasmussen and Zandieh on Models; References; Section 2: Where Are Models & Modelers Found?
    Description / Table of Contents: Chapter 6: Modeling to Address Techno-Mathematical Literacies in Work6.1 Introduction; 6.2 Methodology; 6.3 Findings; 6.4 Results; 6.4.1 Two Examples: Manufacturing and Statistical Process Control; 6.5 Conclusions; References; Chapter 7: Mathematical Modeling in Engineering Design Projects; 7.1 Introduction; 7.2 Methodology; 7.2.1 Industrial Engineering Undergraduates; 7.2.2 Mechanical Engineering Graduate Students; 7.3 Discussion; 7.4 Conclusion; References; Chapter 8: The Mathematical Expertise of Mechanical Engineers - The Case of Mechanism Design; 8.1 Introduction
    Description / Table of Contents: 8.2 Method of Investigation8.3 The Task: Design of Part of a Cutting Device; 8.4 Results and Discussion; 8.5 Conclusions; References; Section 3: What Do Modeling Processes Look Like?; Chapter 9: Modeling and Quantitative Reasoning: The Summer Jobs Problem; 9.1 Theoretical Framework; 9.2 Methods; 9.3 Results; 9.3.1 What Is the Students' Model?; 9.3.2 What Is the Role of Quantities in Students' Models?; 9.3.3 What Is the Role of Quantitative Reasoning in Students' Models?; 9.3.4 What Is the Relationship Between Quantitative Reasoning and Model Development?; 9.4 Discussion; References
    Description / Table of Contents: Chapter 10: Tracing Students' Modeling Processes in School10.1 Introduction; 10.2 Theoretical Framework; 10.3 The Present Study; 10.3.1 The Purpose of the Study; 10.3.2 Participants, Modelling Activity, and Procedures; 10.3.3 Data Sources and Analysis; 10.4 Results; 10.4.1 Modelling Processes; 10.4.2 Mathematical Developments; 10.5 Discussion; References; Section 4: What Creates "The Need For Modeling"; Chapter 11: Turning Ideas into Modeling Problems; 11.1 Introduction; 11.2 Approaches to Mathematical Modeling; 11.2.1 Modeling as Vehicle; 11.2.2 Modeling as Content
    Description / Table of Contents: 11.3 Educational Rationale
    Note: Includes bibliographical references and index
    DOI: 10.1007/978-94-007-6271-8
    URL: Volltext
    URL: Volltext
    URL: Cover
    URL: Inhaltstext
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  • 7
    Online Resource
    Online Resource
    Advances in Nature of Science Research : Concepts and Methodologies (2012)
    Dordrecht : Springer Science+Business Media B.V
    Details
    ISBN: 9789400724570 , 1283456427 , 9781283456425
    Language: English
    Pages: Online-Ressource (X, 268p. 16 illus, digital)
    Series Statement: SpringerLink
    Series Statement: Bücher
    Parallel Title: Buchausg. u.d.T. Advances in nature of science research
    RVK:
    DP 4600
    RVK:
    VB 4052
    RVK:
    UB 4049
    RVK:
    TB 4053
    RVK:
    SM 630
    Keywords: Curriculum planning ; Science Study and teaching ; Education ; Education ; Curriculum planning ; Science Study and teaching ; Science ; Study and teaching ; Science ; Philosophy ; Wissenschaft ; Wissenschaftstheorie ; Empirische Forschung ; Naturwissenschaftlicher Unterricht
    Abstract: This book consolidates contemporary thinking and research efforts in teaching and learning about the nature of science in science education. The term 'Nature of Science' (NoS) has appeared in the science education literature for many decades. While there is still a controversy among science educators about what constitutes NoS, educators are unanimous in acknowledging the importance of this topic as well as the need to make it explicit in teaching science. The general consensus is that the nature of science is an intricate and multifaceted theme that requires continued scholarship
    Abstract: This book consolidates contemporary thinking and research efforts in teaching and learning about the nature of science in science education. The term 'Nature of Science' (NoS) has appeared in the science education literature for many decades. While there is still a controversy among science educators about what constitutes NoS, educators are unanimous in acknowledging the importance of this topic as well as the need to make it explicit in teaching science. The general consensus is that the nature of science is an intricate and multifaceted theme that requires continued scholarship. Recent anal
    Description / Table of Contents: pt. 1. Conceptual issues in the nature of science research -- pt. 2. Methodological advances in the nature of science research.
    Note: Includes bibliographical references and index
    DOI: 10.1007/978-94-007-2457-0
    URL: Volltext
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    URL: Cover
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  • 8
    Online Resource
    Online Resource
    Models and Modeling : Cognitive Tools for Scientific Enquiry (2011)
    Dordrecht : Springer Science+Business Media B.V
    Details
    ISBN: 1283086115 , 9789400704497 , 9781283086110
    Language: English
    Pages: Online-Ressource , v.: digital
    Edition: Online-Ausg. Springer eBook Collection. Humanities, Social Science and Law Electronic reproduction; Available via World Wide Web
    Series Statement: Models and Modeling in Science Education 6
    DDC: 507.1
    RVK:
    DP 4600
    RVK:
    DP 4630
    RVK:
    SM 630
    RVK:
    TB 4053
    RVK:
    UB 4049
    RVK:
    VB 4052
    RVK:
    WB 1027
    Keywords: Education ; Science Study and teaching
    Abstract: The process of developing models, known as modeling, allows scientists to visualize difficult concepts, explain complex phenomena and clarify intricate theories. In recent years, science educators have greatly increased their use of modeling in teaching, especially real-time dynamic modeling, which is central to a scientific investigation. Modeling in science teaching is being used in an array of fields, everything from primary sciences to tertiary chemistry to college physics, and it is sure to play an increasing role in the future of education. Models and Modeling: Cognitive Tools for Scientific Enquiry is a comprehensive introduction to the use of models and modeling in science education. It identifies and describes many different modeling tools and presents recent applications of modeling as a cognitive tool for scientific enquiry.
    Description / Table of Contents: pt. 1. Theory formation and modeling in science education -- pt. 2. Modeling and student learning in science educatin -- pt. 3. Modeling and teachers' knowledge.
    Note: Includes bibliographical references and indexes , Electronic reproduction; Available via World Wide Web
    DOI: 10.1007/978-94-007-0449-7
    URL: Volltext  (lizenzpflichtig)
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  • 9
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    Online Resource
    The Pedagogy of Physical Science (2010)
    Dordrecht : Springer Science+Business Media B.V
    Details
    ISBN: 9781402052712
    Language: English
    Pages: Online-Ressource , v.: digital
    Edition: Online-Ausg. Springer eBook Collection. Humanities, Social Science and Law Electronic reproduction; Available via World Wide Web
    Series Statement: Contemporary Trends and Issues in Science Education 38
    DDC: 507.1
    RVK:
    UB 4049
    Keywords: Education ; Science Study and teaching ; Physikunterricht
    Abstract: In the science classroom, there are some ideas that are as difficult for young students to grasp as they are for teachers to explain. Forces, electricity, light, and basic astronomy are all examples of conceptual domains that come into this category. How should a teacher teach them? The authors of this monograph reject the traditional separation of subject and pedagogic knowledge. They believe that to develop effective teaching for meaningful learning in science, we must identify how teachers themselves interpret difficult ideas in science and, in particular, what supports their own learning in coming to a professional understanding of how to teach science concepts to young children. To do so, they analyzed trainee and practising teachers' responses to engaging with difficult ideas when learning science in higher education settings. The text demonstrates how professional insight emerges as teachers identify the elements that supported their understanding during their own learning. In this paradigm, professional awareness derives from the practitioner interrogating their own learning and identifying implications for their teaching of science. The book draws on a significant body of critically analysed empirical evidence collated and documented over a five-year period involving large numbers of trainee and practising teachers. It concludes that it is essential to 'problematize' subject knowledge, both for learner and teacher. The book's theoretical perspective draws on the field of cognitive psychology in learning. In particular, the role of metacognition and cognitive conflict in learning are examined and subsequently applied in a range of contexts. The work offers a unique and refreshing approach in addressing the important professional dimension of supporting teacher understanding of pedagogy and critically examines assumptions in contemporary debates about constructivism in science education.
    Description / Table of Contents: 138516_1_En_BookFrontmatter_OnlinePDF; 138516_1_En_1_Chapter_OnlinePDF; 138516_1_En_2_Chapter_OnlinePDF; 138516_1_En_3_Chapter_OnlinePDF; 138516_1_En_4_Chapter_OnlinePDF; 138516_1_En_5_Chapter_OnlinePDF; 138516_1_En_6_Chapter_OnlinePDF; 138516_1_En_7_Chapter_OnlinePDF; 138516_1_En_BookBackmatter_OnlinePDF;
    Note: Includes bibliographical references and index , Electronic reproduction; Available via World Wide Web
    DOI: 10.1007/978-1-4020-5271-2
    URL: Volltext  (lizenzpflichtig)
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    MPI Ethno. Forsch.
  • 10
    Online Resource
    Online Resource
    Modeling Students' Mathematical Modeling Competencies : ICTMA 13 (2010)
    Boston, MA : Springer Science+Business Media, LLC
    Details
    ISBN: 9781441905611
    Language: English
    Pages: Online-Ressource , v.: digital
    Edition: 1
    Edition: Online-Ausg. Springer eBook Collection. Humanities, Social Science and Law Electronic reproduction; Available via World Wide Web
    RVK:
    SD 2007
    RVK:
    SM 603
    RVK:
    SM 619
    RVK:
    DP 4600
    RVK:
    SM 630
    RVK:
    TB 4053
    RVK:
    UB 4049
    RVK:
    VB 4052
    Keywords: Education ; Mathematics ; Science Study and teaching ; Mathematikunterricht ; Mathematisches Modell ; Fähigkeit
    Abstract: As we enter the 21st century, there is an urgent need for new approaches to mathematics education emphasizing its relevance in young learners' futures. Modeling Students' Mathematical Modeling Competencies explores the vital trend toward using real-world problems as a basis for teaching mathematics skills, competencies, and applications. Blending theoretical constructs and practical considerations, the book presents papers from the latest conference of the ICTMA, beginning with the basics (Why are models necessary? Where can we find them?) and moving through intricate concepts of how students perceive math, how instructors teach and how both can become better learners. Dispatches as varied as classroom case studies, analyses of math in engineering work, and an in-depth review of modeling-based curricula in the Netherlands illustrate modeling activities on the job, methods of overcoming math resistance, and the movement toward replicable models and lifelong engagement. A sampling of topics covered: How students recognize the usefulness of mathematics Creating the modeling-oriented classroom Assessing and evaluating students' modeling capabilities The relationship between modeling and problem-solving Instructor methods for developing their own models of modeling New technologies for modeling in the classroom Modeling Students' Mathematical Modeling Competencies offers welcome clarity and focus to the international research and professional community in mathematics, science, and engineering education, as well as those involved in the sciences of teaching and learning these subjects.
    Note: Includes bibliographical references , Electronic reproduction; Available via World Wide Web
    DOI: 10.1007/978-1-4419-0561-1
    URL: Volltext  (lizenzpflichtig)
    URL: Inhaltstext
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  • 11
    Online Resource
    Online Resource
    The Pendulum : Scientific, Historical, Philosophical and Educational Perspectives (2005)
    Dordrecht : Springer
    Details
    ISBN: 9781402035265
    Language: English
    Pages: Online-Ressource (VII, 542 S.) , v.: digital
    Edition: Online-Ausg. Springer eBook Collection. Humanities, Social Science and Law Electronic reproduction; Available via World Wide Web
    Parallel Title: Druckausg. Matthews, Michael R., 1948 - The Pendulum
    DDC: 507.1
    RVK:
    UF 1950
    RVK:
    NU 2000
    Keywords: Education ; Mathematics ; Science Study and teaching ; Teachers Training of ; Mechanics ; Physics History ; Pendel
    Abstract: The pendulum is a universal topic in primary and secondary schools, but its full potential for learning about physics, the nature of science, and the relationships between science, mathematics, technology, society and culture is seldom realised. Contributions to this 32-chapter anthology deal with the science, history, methodology and pedagogy of pendulum motion. There is ample material for the richer and more cross-disciplinary treatment of the pendulum from elementary school to high school, and through to advanced university classes. Scientists will value the studies on the physics of the pendulum, historians will appreciate the detailed treatment of Galileo, Huygens, Newton and Foucault's pendulum investigations, psychologists and educators will learn from the papers on Piaget, teachers will welcome the many contributions to pendulum pedagogy. All readers will come away with a new awareness of the importance of the pendulum in the foundation and development of modern science, and for its centrality in so many facets of society and culture.
    Description / Table of Contents: The Pendulum: Its Place in Science, Culture and Pedagogy; The Pendulum in the 21st Century-Relic or Trendsetter; The Pendulum: A Paradigm for the Linear Oscillator; Introduction to the Treatment of Non-Linear Effects Using a Gravitational Pendulum; Experimental Control of Simple Pendulum Model; Soup-can Pendulum; What Makes the Foucault Pendulum Move among the Stars?; Galileo and the Pendulum: Latching on to Time; The Treatment of Cycloidal Pendulum Motion in Newton's Principia; Pendulums, Pedagogy, and Matter: Lessons from the Editing of Newton's Principia
    Description / Table of Contents: The Treatment of the Motion of a Simple Pendulum in Some Early 18th Century Newtonian TextbooksNewton's Path to Universal Gravitation: The Role of the Pendulum; Léon Foucault: His Life, Times and Achievements; The Pendulum: From Constrained Fall to the Concept of Potential; Idealisation and Galileo's Pendulum Discoveries: Historical, Philosophical and Pedagogical Considerations; Pendula, Models, Constructivism and Reality; The Poet and the Pendulum; Methodology and Politics: A Proposal to Teach the Structuring Ideas of the Philosophy of Science through the Pendulum
    Description / Table of Contents: Degree of Influence on Perception of Belief and Social Setting: Its Relevance to Understanding Pendulum MotionPiaget and the Pendulum; What the Pendulum Can Tell Educators about Children's Scientific Reasoning; Pendulum Phenomena and the Assessment of Scientific Inquiry Capabilities; Roles of Abductive Reasoning and Prior Belief in Children's Generation of Hypotheses about Pendulum Motion; Types of Two-Dimensional Pendulums and Their Uses in Education; The Pendulum as a Vehicle for Transitioning from Classical to Quantum Physics: History, Quantum Concepts, and Educational Challenges
    Description / Table of Contents: Analyzing Dynamic Pendulum Motion in an Interactive Online Environment Using FlashPendulum Activities in the Israeli Physics Curriculum: Used and Missed Opportunities; The Pendulum as Presented in School Science Textbooks of Greece and Cyprus; The Public Understanding of Pendulum Motion: From 5 to 88 Years Old; Using Excel to Simulate Pendulum Motion and Maybe Understand Calculus a Little Better; Teaching Cultural History from Primary Events; Pendulums in The Physics Education Literature: A Bibliography
    Note: Includes bibliographical references and indexes , Partly reprinted from Science & Education Vol 13, nos. 4-5 and 7-8 , Electronic reproduction; Available via World Wide Web
    DOI: 10.1007/1-4020-3526-8
    URL: Volltext  (lizenzpflichtig)
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  • 12
    Online Resource
    Online Resource
    Evaluation of Science and Technology Education at the Dawn of a New Millennium (2002)
    Dordrecht : Imprint: Springer | Dordrecht : Springer Netherlands
    Details
    ISBN: 9780306475603
    Language: English
    Pages: 1 Online-Ressource(XVI, 279 p.)
    Edition: 1st ed. 2002.
    Series Statement: Innovations in Science Education and Technology 14
    Parallel Title: Erscheint auch als
    Parallel Title: Erscheint auch als
    RVK:
    DF 2602
    RVK:
    UB 4080
    Keywords: Assessment. ; Science education. ; School management and organization. ; School administration. ; Educational tests and measurements. ; Science—Study and teaching. ; Education ; Science Study and teaching ; Educational tests and measurements ; USA ; Technische Bildung
    Abstract: What Does the Future Have in Store for the Evaluation of Science and Technology Education? -- What Role Should TIMSS Play in the Evaluation of U.S. Science Education? -- Evaluating Systemic Reform -- Musings on Science Program Evaluation in an Era of Educational Accountability -- Assessment Reform -- Evaluation of Information Technology -- Complementary Approaches to Evaluating Technology in Science Teacher Education -- Evaluation of Science Teaching Performance through Coteaching and Cogenerative Dialoguing -- Evaluating Science Inquiry -- Distance Learning in Science Education.
    Abstract: "James Altschuld, David Kumar, and their chapter authors have produced an upbeat, provocative, visionary, and useful volume on educational evaluation. Of special utility is its grounding in issues and practices relating to evaluations of science and technology education. The book should appeal and be useful to a wide range of persons involved in evaluations of educational policy, programs, and (less so) science teachers. These persons include science and technology education experts, educational policymakers, officials of the National Science Foundation, school administrators, classroom teachers, evaluation instructors, evaluation methodologists, practicing evaluators, and test developers, among others. Contents reflecting international studies of curriculum, evaluation of distance education, and evaluation of technology utilization in Australian schools, as well as evaluations in America should make the book appealing to an international audience. Moreover, it provides a global perspective for assessing and strengthening educational evaluation in the US." Daniel L. Stufflebeam, Professor of Education and Director of the Evaluation Center, Western Michigan University For contents, contributors and a free preview: www.new-in-education.com.
    Description / Table of Contents: ""Contents""
    Note: Includes bibliographical references and index
    DOI: 10.1007/0-306-47560-X
    URL: lizenzpflichtig
    URL: Volltext
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    MPI Ethno. Forsch.
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