Are you interested in using argument-driven inquiry for middle school lab instruction but just aren’t sure how to do it? Argument-Driven Inquiry in Physical Science will provide you with both the information and instructional materials you need to start using this method right away. The book is a one-stop source of expertise, advice, and investigations to help physical science students work the way scientists do. Student Lab Manual for Argument-Driven Inquiry in Life Science provides the student materials you need to guide your students through these investigations. With lab details, student handouts, and safety information, your students will be ready to start investigating.
Are you interested in using argument-driven inquiry for middle school lab instruction but just aren’t sure how to do it? Argument-Driven Inquiry in Physical Science will provide you with both the information and instructional materials you need to start using this method right away. The book is a one-stop source of expertise, advice, and investigations to help physical science students work the way scientists do. The book is divided into two basic parts: 1. An introduction to the stages of argument-driven inquiry—from question identification, data analysis, and argument development and evaluation to double-blind peer review and report revision. 2. A well-organized series of 22 field-tested labs designed to be much more authentic for instruction than traditional laboratory activities. The labs cover four core ideas in physical science: matter, motion and forces, energy, and waves. Students dig into important content and learn scientific practices as they figure out everything from how thermal energy works to what could make an action figure jump higher. The authors are veteran teachers who know your time constraints, so they designed the book with easy-to-use reproducible student pages, teacher notes, and checkout questions. The labs also support today’s standards and will help your students learn the core ideas, crosscutting concepts, and scientific practices found in the Next Generation Science Standards. In addition, the authors offer ways for students to develop the disciplinary skills outlined in the Common Core State Standards. Many of today’s middle school teachers—like you—want to find new ways to engage students in scientific practices and help students learn more from lab activities. Argument-Driven Inquiry in Physical Science does all of this while also giving students the chance to practice reading, writing, speaking, and using math in the context of science.
Are you interested in a three-dimensional approach to helping your high school physics students learn the practices of science, including constructing explanations and engaging in argument from evidence? By using argument-driven inquiry (ADI) for high school physics lab instruction, you can do just that. Argument-Driven Inquiry in Physics, Volume 2 provides the information and instructional materials you need to start using this method right away for electricity and magnetism investigations. The book is a one-stop source of expertise, advice, and lessons to help physics students work the way scientists do. The book is divided into three parts: * An introduction to argument-driven inquiry and how to use the labs. You' ll learn about the stages of ADI, from question identification, data analysis, and argument development and evaluation to double-blind peer review and report revision. * A well-organized series of 17 field-tested labs designed to be much more authentic for instruction than traditional laboratory activities. The labs cover a variety of topics, including electrostatics; electric current, capacitors, resistors, and circuits; and magnetic fields and electromagnetism. Introduction labs acquaint students with new content. Application labs encourage deeper exploration of the use of a theory, law, or unifying concept. * Helpful appendixes. These range from timeline options to peer-review guides and teacher scoring rubrics-- including ones for AP physics. ADI in Physics, Volume 2 is a follow-up to ADI in Physics, Volume 1: Mechanics Lab Investigations for Grades 9- 12. Both are part of the NSTA Press series for ADI in biology, chemistry, life science, and physical science. The authors understand your time constraints, so they designed the books with easy-to-use lab handouts, student pages, teacher notes, and checkout questions. The labs also support three-dimensional instruction, helping students learn the science practices, crosscutting concepts, and core ideas found in the Next Generation Science Standards. The labs also support student learning of standards in both algebra- and calculus-based AP Physics courses. In addition, they offer ways for students to develop the disciplinary skills outlined in the Common Core State Standards. Many of today' s high school teachers-- like you-- are seeking new ways to engage students in science practices and help students learn more from lab activities. ADI in Physics, Volume 2 does all of this while also giving your students the chance to practice reading, writing, speaking, and using math in the context of science.
Develop your high school students' understanding of argumentation and evidence-based reasoning with this comprehensive book. Like three guides in one 'Scientific Argumentation in Biology' combines theory, practice, and biology content.
If you' re looking for labs that cover Earth and space science, appeal to middle and high school students, and use Argument-Driven Inquiry (ADI), your search is over. Argument-Driven Inquiry in Earth and Space Science provides 23 field-tested labs that cover the universe, Earth, and weather. It also helps you make the instructional shift to ADI. This innovative approach to inquiry prompts students to use argument to construct, support, and evaluate scientific claims. The book starts with guidance on how to use ADI. Then it provides labs that cover five disciplinary core ideas in Earth and space science: Earth' s place in the universe, the history of Earth, Earth' s systems, weather and climate, and Earth and human activity. Your students will explore important content and discover scientific practices. They can investigate everything from how the seasons work to what causes geological formations and even consider where NASA should send a space probe next to look for signs of life. This volume is the latest in NSTA' s teacher-friendly ADI series. The authors are veteran teachers who know the importance of connecting all investigations to today' s standards-- and of providing the information and instructional materials you need in one useful resource that combines literacy, math, and science. Use these new investigations to help students develop science proficiency by figuring out how and why things work, not just learning theories and laws.
Teaching Chemistry in Higher Education celebrates the contributions of Professor Tina Overton to the scholarship and practice of teaching and learning in chemistry education. Leading educators in United Kingdom, Ireland, and Australia—three countries where Tina has had enormous impact and influence—have contributed chapters on innovative approaches that are well-established in their own practice. Each chapter introduces the key education literature underpinning the approach being described. Rationales are discussed in the context of attributes and learning outcomes desirable in modern chemistry curricula. True to Tina’s personal philosophy, chapters offer pragmatic and useful guidance on the implementation of innovative teaching approaches, drawing from the authors’ experience of their own practice and evaluations of their implementation. Each chapter also offers key guidance points for implementation in readers’ own settings so as to maximise their adaptability. Chapters are supplemented with further reading and supplementary materials on the book’s website (overtonfestschrift.wordpress.com). Chapter topics include innovative approaches in facilitating group work, problem solving, context- and problem-based learning, embedding transferable skills, and laboratory education—all themes relating to the scholarly interests of Professor Tina Overton. About the Editors: Michael Seery is Professor of Chemistry Education at the University of Edinburgh, and is Editor of Chemistry Education Research and Practice. Claire Mc Donnell is Assistant Head of School of Chemical and Pharmaceutical Sciences at Technological University Dublin. Cover Art: Christopher Armstrong, University of Hull
Biology Inquiries offers educators a handbook for teaching middle and high school students engaging lessons in the life sciences. Inspired by the National Science Education Standards, the book bridges the gap between theory and practice. With exciting twists on standard biology instruction the author emphasizes active inquiry instead of rote memorization. Biology Inquiries contains many innovative ideas developed by biology teacher Martin Shields. This dynamic resource helps teachers introduce standards-based inquiry and constructivist lessons into their classrooms. Some of the book's classroom-tested lessons are inquiry modifications of traditional "cookbook" labs that biology teachers will recognize. Biology Inquiries provides a pool of active learning lessons to choose from with valuable tips on how to implement them.
Laboratory experiences as a part of most U.S. high school science curricula have been taken for granted for decades, but they have rarely been carefully examined. What do they contribute to science learning? What can they contribute to science learning? What is the current status of labs in our nation�s high schools as a context for learning science? This book looks at a range of questions about how laboratory experiences fit into U.S. high schools: What is effective laboratory teaching? What does research tell us about learning in high school science labs? How should student learning in laboratory experiences be assessed? Do all student have access to laboratory experiences? What changes need to be made to improve laboratory experiences for high school students? How can school organization contribute to effective laboratory teaching? With increased attention to the U.S. education system and student outcomes, no part of the high school curriculum should escape scrutiny. This timely book investigates factors that influence a high school laboratory experience, looking closely at what currently takes place and what the goals of those experiences are and should be. Science educators, school administrators, policy makers, and parents will all benefit from a better understanding of the need for laboratory experiences to be an integral part of the science curriculum-and how that can be accomplished.
