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External representations (pictures, diagrams, graphs, concrete models) have always been valuable tools for the science teacher. This book brings together the insights of practicing scientists, science education researchers, computer specialists, and cognitive scientists, to produce a coherent overview. It links presentations about cognitive theory, its implications for science curriculum design, and for learning and teaching in classrooms and laboratories.
Visual Data in Science Education builds upon previous work done by the editors to bring some definition to the meaning of visual data as it relates to education, and highlighted the breadth of types and uses of visual data across the major academic disciplines. In this book, the editors have brought this focus specifically to science education through the contributions of colleagues in the field who actively research about and engage in teaching with visual data. The book begins by examining how the brain functions with respect to processing visual data, then explores models of conceptual frameworks, which then leads into how related ideas are actuated in education settings ranging from elementary science classrooms to college environments. As a whole, this book fosters a more coherent image of the multifaceted process of science teaching and learning that is informed by current understandings of science knowledge construction, the scientific enterprise, and the millennium student as they relate to visual data.
2014 Outstanding Academic Title, Choice "What’s going on in this picture?" With this one question and a carefully chosen work of art, teachers can start their students down a path toward deeper learning and other skills now encouraged by the Common Core State Standards. The Visual Thinking Strategies (VTS) teaching method has been successfully implemented in schools, districts, and cultural institutions nationwide, including bilingual schools in California, West Orange Public Schools in New Jersey, and the San Francisco Museum of Modern Art. It provides for open-ended yet highly structured discussions of visual art, and significantly increases students’ critical thinking, language, and literacy skills along the way. Philip Yenawine, former education director of New York’s Museum of Modern Art and cocreator of the VTS curriculum, writes engagingly about his years of experience with elementary school students in the classroom. He reveals how VTS was developed and demonstrates how teachers are using art—as well as poems, primary documents, and other visual artifacts—to increase a variety of skills, including writing, listening, and speaking, across a range of subjects. The book shows how VTS can be easily and effectively integrated into elementary classroom lessons in just ten hours of a school year to create learner-centered environments where students at all levels are involved in rich, absorbing discussions.
Learn how to teach visual literacy through photography—an easy way for you to combine student interest with resources at hand to enhance a key learning skill. Research indicates that 75 to 90 percent of classroom learning occurs through the visual system, making visual literacy a key component of information literacy and of critical thinking—a requirement throughout the Common Core standards. It's no surprise then that visual literacy is increasingly recognized as a competency that should be part of every student's skill set. Fortunately, this critical skill can be incorporated into existing curriculum, and this book shows you how to do just that. Written for K–12 classroom teachers and librarians, this all-you-need-to-know volume discusses the importance of visual literacy in education and examines how it helps address current learning standards. The book shows you how to use photography and digital images to cultivate critical thinking, inquiry, and information literacy; provides examples of the use of photographic images in the classroom and in "real life"; and addresses how students can be ethical practitioners in a digital world. In addition, the book includes sample lessons you can easily implement, regardless of your level of technical and photographic expertise. A resource list of photo editing, curation, and museum sites is included.
Prompted by the ongoing debate among science educators over ‘nature of science’, and its importance in school and university curricula, this book is a clarion call for a broad re-conceptualizing of nature of science in science education. The authors draw on the ‘family resemblance’ approach popularized by Wittgenstein, defining science as a cognitive-epistemic and social-institutional system whose heterogeneous characteristics and influences should be more thoroughly reflected in science education. They seek wherever possible to clarify their developing thesis with visual tools that illustrate how their ideas can be practically applied in science education. The volume’s holistic representation of science, which includes the aims and values, knowledge, practices, techniques, and methodological rules (as well as science’s social and institutional contexts), mirrors its core aim to synthesize perspectives from the fields of philosophy of science and science education. The authors believe that this more integrated conception of nature of science in science education is both innovative and beneficial. They discuss in detail the implications for curriculum content, pedagogy, and learning outcomes, deploy numerous real-life examples, and detail the links between their ideas and curriculum policy more generally.
The visual inputs we receive can be collectively called visual data. Precisely how one defines visual data is a key question to ask. That is one of the questions we asked each author who wrote a chapter for this book. If one comes to a decision with respect to what visual data are, then the next question becomes, "What are visual data like?" Then, "What do they mean?" As with any data, we can collect it and compile it, but if we don't have some way to bring meaning it, it has little value to us. The answers may not be as straightforward as one might assume at the outset. The extent to which visual data permeates what we do as educators is such that it may be difficult to identify every discipline in which it emerges. In this book, we have tried to provide a forum for authors from a cross section of common disciplines: visual arts, English, literacy, mathematics, science, social science, and even higher education administration.
This book addresses key issues concerning visualization in the teaching and learning of science at any level in educational systems. It is the first book specifically on visualization in science education. The book draws on the insights from cognitive psychology, science, and education, by experts from five countries. It unites these with the practice of science education, particularly the ever-increasing use of computer-managed modelling packages.
This book illustrates the problems of using eye tracking technology and other bio-measurements in science education research. It examines the application of bio-measurements in researching cognitive processes, motivation for learning science concepts, and solving science problems. Most chapters of this book use the eye-tracking method, which enables following the focus of the students’ attention and drawing conclusions about the strategies they used to solve the problem. This book consists of a total of fifteen chapters. Authors from eight countries emphasise the same trends despite their cultural and educational differences. The book begins with general chapters describing cognitive processes and how these processes are measured using eye-tracking methods and other psychophysiology parameters and motivation. Finally, the book concludes the chapters presenting studies in specific scientific fields from chemistry, biology, physics and geology.
Science education at school level worldwide faces three perennial problems that have become more pressing of late. These are to a considerable extent interwoven with concerns about the entire school curriculum and its reception by students. The rst problem is the increasing intellectual isolation of science from the other subjects in the school curriculum. Science is too often still taught didactically as a collection of pre-determined truths about which there can be no dispute. As a con- quence, many students do not feel any “ownership” of these ideas. Most other school subjects do somewhat better in these regards. For example, in language classes, s- dents suggest different interpretations of a text and then debate the relative merits of the cases being put forward. Moreover, ideas that are of use in science are presented to students elsewhere and then re-taught, often using different terminology, in s- ence. For example, algebra is taught in terms of “x, y, z” in mathematics classes, but students are later unable to see the relevance of that to the meaning of the universal gas laws in physics, where “p, v, t” are used. The result is that students are c- fused and too often alienated, leading to their failure to achieve that “extraction of an education from a scheme of instruction” which Jerome Bruner thought so highly desirable.