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How is epistemology related to the issue of teaching science and evolution in the schools? Addressing a flashpoint issue in our schools today, this book explores core epistemological differences between proponents of intelligent design and evolutionary scientists, as well as the critical role of epistemological beliefs in learning science. Preeminent scholars in these areas report empirical research and/or make a theoretical contribution, with a particular emphasis on the controversy over whether intelligent design deserves to be considered a science alongside Darwinian evolution. This pioneering book coordinates and provides a complete picture of the intersections in the study of evolution, epistemology, and science education, in order to allow a deeper understanding of the intelligent design vs. evolution controversy. This is a very timely book for teachers and policy makers who are wrestling with issues of how to teach biology and evolution within a cultural context in which intelligent design has been and is likely to remain a challenge for the foreseeable future.
This pioneering book coordinates and provides a complete picture of the intersections in the study of evolution, epistemology, and science education, in order to allow a deeper understanding of the intelligent design vs. evolution controversy.
Currents such as epistemological and social constructivism, postmodernism, and certain forms of multiculturalism that had become fashionable within science education circles in the last decades lost sight of critical inquiry as the core aim of education. In this book we develop an account of education that places critical inquiry at the core of education in general and science education in particular. Since science constitutes the paradigm example of critical inquiry, we explain the nature of science, paying particular attention to scientific methodology and scientific modeling and at the same time showing their relevance in the science classroom. We defend a universalist, rationalist, and objectivist account of science against epistemological and social constructivist views, postmodernist approaches and epistemic multiculturalist accounts.
Science Teaching argues that science teaching and science teacher education can be improved if teachers know something of the history and philosophy of science and if these topics are included in the science curriculum. The history and philosophy of science have important roles in many of the theoretical issues that science educators need to address: what constitutes an appropriate science curriculum for all students; how science should be taught in traditional cultures; how scientific literacy can be promoted; and the conflict which can occur between science curriculum and deep-seated religious or cultural values and knowledge. Outlining the history of liberal approaches to the teaching of science, Michael Matthews elaborates contemporary curriculum developments that explicitly address questions about the nature and the history of science. He provides examples of classroom teaching and develops useful arguments on constructivism, multicultural science education and teacher education.
The Oxford Handbook of Epistemology contains 19 previously unpublished chapters by today's leading figures in the field. These chapters function not only as a survey of key areas, but as original scholarship on a range of vital topics. Written accessibly for advanced undergraduates, graduate students, and professional philosophers, the Handbook explains the main ideas and problems of contemporary epistemology while avoiding overly technical detail.
What Is Scientific Knowledge? is a much-needed collection of introductory-level chapters on the epistemology of science. Renowned historians, philosophers, science educators, and cognitive scientists have authored 19 original contributions specifically for this volume. The chapters, accessible for students in both philosophy and the sciences, serve as helpful introductions to the primary debates surrounding scientific knowledge. First-year undergraduates can readily understand the variety of discussions in the volume, and yet advanced students and scholars will encounter chapters rich enough to engage their many interests. The variety and coverage in this volume make it the perfect choice for the primary text in courses on scientific knowledge. It can also be used as a supplemental book in classes in epistemology, philosophy of science, and other related areas. Key features: * an accessible and comprehensive introduction to the epistemology of science for a wide variety of students (both undergraduate- and graduate-level) and researchers * written by an international team of senior researchers and the most promising junior scholars * addresses several questions that students and lay people interested in science may already have, including questions about how scientific knowledge is gained, its nature, and the challenges it faces.
Educational researchers are bound to see this as a timely work. It brings together the work of leading experts in argumentation in science education. It presents research combining theoretical and empirical perspectives relevant for secondary science classrooms. Since the 1990s, argumentation studies have increased at a rapid pace, from stray papers to a wealth of research exploring ever more sophisticated issues. It is this fact that makes this volume so crucial.
Epistemologies of Ignorance provide educators a distinct epistemological view on questions of marginalization, oppression, relations of power and dominance, difference, philosophy, and even death among our youth. The authors of this edited collection challenge the ambivalence – ignorance – found in the construction of curriculum, teaching practices, research guidelines, and policy mandates in our schools. Further, ignorance is also considered a necessary by- product of knowledge production. In this sense, the authors explore not only issues of complicity but also issues of oppression in spite of educators’ liberatory intentions. While this is the first systematic effort to transfer epistemologies of ignorance to the educational scene, this movement has its roots in race, class, gender, and sexuality studies, particularly the work of Charles Mills, Eve Kosofsky Sedgwick, Shannon Sullivan, and Nancy Tuana. It is our unequivocal belief that, while this is transformative and powerful scholarship, the study of ignorance remains understudied and under-theorized in education scholarship, from curriculum studies and cultural foundations to science education and educational psychology. This collection highlights without apology why this dangerous state of affairs cannot continue.
What are scientific inquiry practices like today? How should schools approach inquiry in science education? Teaching Science Inquiry presents the scholarly papers and practical conversations that emerged from the exchanges at a two-day conference of distinctive North American ‘science studies’ and ‘learning science’scholars.
This book, by combining sociocultural, material, cognitive and embodied perspectives on human knowing, offers a new and powerful conceptualisation of epistemic fluency – a capacity that underpins knowledgeable professional action and innovation. Using results from empirical studies of professional education programs, the book sheds light on practical ways in which the development of epistemic fluency can be recognised and supported - in higher education and in the transition to work. The book provides a broader and deeper conception of epistemic fluency than previously available in the literature. Epistemic fluency involves a set of capabilities that allow people to recognize and participate in different ways of knowing. Such people are adept at combining different kinds of specialised and context-dependent knowledge and at reconfiguring their work environment to see problems and solutions anew. In practical terms, the book addresses the following kinds of questions. What does it take to be a productive member of a multidisciplinary team working on a complex problem? What enables a person to integrate different types and fields of knowledge, indeed different ways of knowing, in order to make some well-founded decisions and take actions in the world? What personal knowledge resources are entailed in analysing a problem and describing an innovative solution, such that the innovation can be shared in an organization or professional community? How do people get better at these things; and how can teachers in higher education help students develop these valued capacities? The answers to these questions are central to a thorough understanding of what it means to become an effective knowledge worker and resourceful professional.