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When analogies are effective, they readily engage students' interest and clarify difficult and abstract ideas. But not all analogies are created equal, and developing them is not always intuitive. Drawing from an extensive research base on the use of analogies in the classroom, Allan Harrison, Richard K. Coll, and a team of science experts come to the rescue with more than 40 teacher-friendly, ready-to-use analogies for biology, earth and space studies, chemistry, and physics. The rich material shows teachers how and when to select analogies for instruction, why certain analogies work or break down, how to gauge their effectiveness, and how to improve them. Designed to enhance teachers' presentation and interpretation of analogies through focus, action, and reflection (FAR), this guidebook includes: Key science concepts explained through effective models and analogies, Research findings on the use of analogies and their motivational impact, Guidelines that allow teachers and students to develop their own analogies, Numerous visual aids, science vignettes, and anecdotes to support the use of analogies. Linked to NSTA standards, Using Analogies in Middle and Secondary Science Classrooms will become a much-used resource by teachers who want to enrich inquiry-based science instruction. Book jacket.
This book brings together powerful ideas and new developments from internationally recognised scholars and classroom practitioners to provide theoretical and practical knowledge to inform progress in science education. This is achieved through a series of related chapters reporting research on analogy and metaphor in science education. Throughout the book, contributors not only highlight successful applications of analogies and metaphors, but also foreshadow exciting developments for research and practice. Themes include metaphor and analogy: best practice, as reasoning; for learning; applications in teacher development; in science education research; philosophical and theoretical foundations. Accordingly, the book is likely to appeal to a wide audience of science educators –classroom practitioners, student teachers, teacher educators and researchers.
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.
The focus of this Handbook is on Australasia (a region loosely recognized as that which includes Australia and New Zealand plus nearby Pacific nations such as Papua New Guinea, Solomon Islands, Fiji, Tonga, Vanuatu, and the Samoan islands) science education and the scholarship that most closely supports this program.
This book goes beyond neuroscience explanations of learning to demonstrate exactly what works in the classroom and why. Lessons from mind, brain and education science are put into practice using students as a "lab" to test these theories. Strategies and approaches for doing so and a general list of "best practices" will guide and serve teachers, administrators and parents. -- Provided by publisher.
This book argues that modelling should be a component of all school curricula that aspire to provide ‘authentic science education for all’. The literature on modelling is reviewed and a ‘model of modelling’ is proposed. The conditions for the successful implementation of the ‘model of modelling’ in classrooms are explored and illustrated from practical experience. The roles of argumentation, visualisation, and analogical reasoning, in successful modelling-based teaching are reviewed. The contribution of such teaching to both the learning of key scientific concepts and an understanding of the nature of science are established. Approaches to the design of curricula that facilitate the progressive grasp of the knowledge and skills entailed in modelling are outlined. Recognising that the approach will both represent a substantial change from the ‘content-transmission’ approach to science teaching and be in accordance with current best-practice in science education, the design of suitable approaches to teacher education are discussed. Finally, the challenges that modelling-based education pose to science education researchers, advanced students of science education and curriculum design, teacher educators, public examiners, and textbook designers, are all outlined.
The focus of this book is on exploring effective strategies in higher education that promote meaningful learning and go beyond discipline boundaries, with a special emphasis on Subjectivity Learning, Refreshing Lecturing, Learning through Construction, Learning through Transaction, Transformative Learning, Using Technology, and Assessment for Learning and Teaching in particular. The research collected in this book is all based on empirical studies and includes research methods and findings that will be of great interest to teachers and researchers in the area of higher education. The main benefit readers will derive from this book is a meaningful insight into what other teachers around the world are doing in higher education and what lessons they have learned, which will support them in their own teaching.
This book discusses the relationship between pluralist economics and the case study method of teaching, advocating the complimentary use of both to advance economics education. Using a multi-paradigmatic philosophical frame of analysis, the book discusses the philosophical, methodological, and practical aspects of the case study method while drawing comparisons with those of the more commonly used lecture method. The book also discusses pluralist economics through the exposition of the philosophical foundations of the extant economics schools of thought, which is the focal point of the attention and admiration of pluralist economics. More specifically, the book discusses the major extant schools of thought in economics – Neo-Classical Economics, New Institutional Economics, Behavioral Economics, Austrian Economics, Post-Keynesian Economics, Institutional Economics, Radical Economics, and Marxist Economics—and emphasizes that these schools of thought in economics are equally scientific and informative, that they look at economic phenomena from their certain paradigmatic viewpoint, and that, together, they provide a more balanced understanding of the economic phenomenon under consideration. Emphasizing paradigmatic diversity as the cornerstone of both the case method and pluralist economics, the book draws the two together and makes an effective case for their combined use. A rigorous, multi-faceted analysis of the philosophy, methodology, and practice of economics education, this book is important for academicians and students interested in heterodox economics, philosophy, and education.
Scientific concepts are abstract human constructions, invented to make sense of complex natural phenomena. Scientists use specialised languages, diagrams, and mathematical representations of various kinds to convey these abstract constructions. This book uses the perspectives of embodied cognition and conceptual metaphor to explore how learners make sense of these concepts. That is, it is assumed that human cognition – including scientific cognition – is grounded in the body and in the material and social contexts in which it is embedded. Understanding abstract concepts is therefore grounded, via metaphor, in knowledge derived from sensory and motor experiences arising from interaction with the physical world. The volume consists of nine chapters that examine a number of intertwined themes: how systematic metaphorical mappings are implicit in scientific language, diagrams, mathematical representations, and the gestures used by scientists; how scientific modelling relies fundamentally on metaphor and can be seen as a form of narrative cognition; how implicit metaphors can be the sources of learner misconceptions; how conceptual change and the acquisition of scientific expertise involve learning to coordinate the use of multiple implicit metaphors; and how effective instruction can build on recognising the embodied nature of scientific cognition and the role of metaphor in scientific thought and learning. The volume also includes three extended commentaries from leading researchers in the fields of cognitive linguistics, the learning sciences, and science education, in which they reflect on theoretical, methodological and pedagogical issues raised in the book. This book was originally published as a special issue of the International Journal of Science Education.