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Formerly a SkyLight publication. Are you looking for new ideas to get students motivated about science? Do you want science lessons that have a high "WOW" factor for students? Hands-On Science for the Active Learning Classroom is a must-have resource for science teachers, offering 90 exciting, inexpensive, and easy-to-use experiments that can be implemented immediately into your daily science lessons. You also can use these activities as high-interest homework assignments, allowing students to take science beyond the classroom and into real-world applications. Hands-On Science reveals active learning at its best and helps you plan activities that motivate and engage student thinking processes in applying scientific knowledge.
How Students Learn: Science in the Classroom builds on the discoveries detailed in the best-selling How People Learn. Now these findings are presented in a way that teachers can use immediately, to revitalize their work in the classroom for even greater effectiveness. Organized for utility, the book explores how the principles of learning can be applied in science at three levels: elementary, middle, and high school. Leading educators explain in detail how they developed successful curricula and teaching approaches, presenting strategies that serve as models for curriculum development and classroom instruction. Their recounting of personal teaching experiences lends strength and warmth to this volume. This book discusses how to build straightforward science experiments into true understanding of scientific principles. It also features illustrated suggestions for classroom activities.
While Active Learning Classrooms, or ALCs, offer rich new environments for learning, they present many new challenges to faculty because, among other things, they eliminate the room’s central focal point and disrupt the conventional seating plan to which faculty and students have become accustomed.The importance of learning how to use these classrooms well and to capitalize on their special features is paramount. The potential they represent can be realized only when they facilitate improved learning outcomes and engage students in the learning process in a manner different from traditional classrooms and lecture halls.This book provides an introduction to ALCs, briefly covering their history and then synthesizing the research on these spaces to provide faculty with empirically based, practical guidance on how to use these unfamiliar spaces effectively. Among the questions this book addresses are:• How can instructors mitigate the apparent lack of a central focal point in the space?• What types of learning activities work well in the ALCs and take advantage of the affordances of the room?• How can teachers address familiar classroom-management challenges in these unfamiliar spaces?• If assessment and rapid feedback are critical in active learning, how do they work in a room filled with circular tables and no central focus point?• How do instructors balance group learning with the needs of the larger class?• How can students be held accountable when many will necessarily have their backs facing the instructor?• How can instructors evaluate the effectiveness of their teaching in these spaces?This book is intended for faculty preparing to teach in or already working in this new classroom environment; for administrators planning to create ALCs or experimenting with provisionally designed rooms; and for faculty developers helping teachers transition to using these new spaces.
This book provides detailed instructional methods on momentum, center of gravity, inertia, and centrifugal and centripetal forces, including hands-on classroom activities and experiments, some utilizing common household materials.
Based on the premise that when students engage in an activity instead of simply reading about it, they understand it better, this book offers 29 hands-on, active learning exercises for use in research methods courses in the social sciences. The activities were created by instructors throughout the United States and tested for effectiveness in their classrooms. They include group activities and solo activities, presented in very accessible language for students. Each exercise is directly related to a concept of research methods and aims to help students become better researchers.
"This open access textbook offers a comprehensive introduction to instruction in all types of library and information settings. Designed for students in library instruction courses, the text is also a resource for new and experienced professionals seeking best practices and selected resources to support their instructional practice. Organized around the backward design approach and written by LIS faculty members with expertise in teaching and learning, this book offers clear guidance on writing learning outcomes, designing assessments, and choosing and implementing instructional strategies, framed by clear and accessible explanations of learning theories. The text takes a critical approach to pedagogy and emphasizes inclusive and accessible instruction. Using a theory into practice approach that will move students from learning to praxis, each chapter includes practical examples, activities, and templates to aid readers in developing their own practice and materials."--Publisher's description.
"Kids love hands-on science. Yet too few grow up to be scientists. Kids need to be reading, writing and thinking about science as well as doing it. Writing in Science in Action propels us full throttle into both hands-on and "minds on" science. Rupp Fulwiler show us how to help kids wrap their minds around science, do science and have a blast in the process. If we really want to prepare kids for an increasingly unpredictable future, we need teachers to read this book and share the practices with the budding young scientists in their rooms." -Stephanie Harvey, author of The Comprehension Toolkit Writing in Science in Action, the highly anticipated follow-up resource to Betsy Rupp Fulwiler's landmark book Writing in Science (Heinemann 2007), offers all new field-tested materials, including 10 video episodes that show teachers as they implement her approach in real classrooms with real children. The Writing in Science in Action online resources brings the content to life by providing clear and explicit models of students talking and writing, and teachers providing the scaffolding, modeling, and conferring needed to support those students.You'll see teachers working in diverse settings with a range of learners, including ELLs, students with special needs, and reluctant writers. You'll also see groups of teachers assessing student notebooks and planning instruction based on their assessments. Focusing on science topics that are accessible and familiar, Fulwiler uses carefully interconnected video episodes, student work, and detailed classroom vignettes to take the reader into the complexity of individual classrooms and the practices of skilled teachers. Seeing her approach in action is a powerful teaching tool, and the online resources, used in combination with the practical text, takes Writing in Science to a whole new level. Seeing really is believing. Writing in Science in Action provides clear guidance and structures for classroom practice, with: * specific strategies that can be immediately used in any classroom * step by step instruction on how to use each strategy * ideas for planning, modeling, scaffolding, and assessment * samples of over 100 student notebook entries with commentaries * techniques for working with ELLs, emergent writers, and struggling students.
Assessments, understood as tools for tracking what and how well students have learned, play a critical role in the classroom. Developing Assessments for the Next Generation Science Standards develops an approach to science assessment to meet the vision of science education for the future as it has been elaborated in A Framework for K-12 Science Education (Framework) and Next Generation Science Standards (NGSS). These documents are brand new and the changes they call for are barely under way, but the new assessments will be needed as soon as states and districts begin the process of implementing the NGSS and changing their approach to science education. The new Framework and the NGSS are designed to guide educators in significantly altering the way K-12 science is taught. The Framework is aimed at making science education more closely resemble the way scientists actually work and think, and making instruction reflect research on learning that demonstrates the importance of building coherent understandings over time. It structures science education around three dimensions - the practices through which scientists and engineers do their work, the key crosscutting concepts that cut across disciplines, and the core ideas of the disciplines - and argues that they should be interwoven in every aspect of science education, building in sophistication as students progress through grades K-12. Developing Assessments for the Next Generation Science Standards recommends strategies for developing assessments that yield valid measures of student proficiency in science as described in the new Framework. This report reviews recent and current work in science assessment to determine which aspects of the Framework's vision can be assessed with available techniques and what additional research and development will be needed to support an assessment system that fully meets that vision. The report offers a systems approach to science assessment, in which a range of assessment strategies are designed to answer different kinds of questions with appropriate degrees of specificity and provide results that complement one another. Developing Assessments for the Next Generation Science Standards makes the case that a science assessment system that meets the Framework's vision should consist of assessments designed to support classroom instruction, assessments designed to monitor science learning on a broader scale, and indicators designed to track opportunity to learn. New standards for science education make clear that new modes of assessment designed to measure the integrated learning they promote are essential. The recommendations of this report will be key to making sure that the dramatic changes in curriculum and instruction signaled by Framework and the NGSS reduce inequities in science education and raise the level of science education for all students.
Wacky Science helps teachers embark on an extremely exciting adventure--teaching hands-on science in the classroom! Gifted students love science, and they particularly love hands-on science. One of the most exciting things about teaching hands-on science is being able to observe how students gravitate toward these motivating activities and their extraordinary ability to extrapolate additional scientific information from the concepts being taught. People of all ages, backgrounds, and educational abilities love to do science that they can directly touch, hear, observe, smell, and experience. This book contains many high-level, abstract scientific concepts that have been developed into hands-on activities. Including experiments in botany, entomology, paleontology, physics, and zoology, among others, these fun, exciting, and highly motivational activities will have students begging for more.
Employ cognitive theory in the classroom every day Research into how we learn has opened the door for utilizing cognitive theory to facilitate better student learning. But that's easier said than done. Many books about cognitive theory introduce radical but impractical theories, failing to make the connection to the classroom. In Small Teaching, James Lang presents a strategy for improving student learning with a series of modest but powerful changes that make a big difference—many of which can be put into practice in a single class period. These strategies are designed to bridge the chasm between primary research and the classroom environment in a way that can be implemented by any faculty in any discipline, and even integrated into pre-existing teaching techniques. Learn, for example: How does one become good at retrieving knowledge from memory? How does making predictions now help us learn in the future? How do instructors instill fixed or growth mindsets in their students? Each chapter introduces a basic concept in cognitive theory, explains when and how it should be employed, and provides firm examples of how the intervention has been or could be used in a variety of disciplines. Small teaching techniques include brief classroom or online learning activities, one-time interventions, and small modifications in course design or communication with students.