New in 2016! Like all enthusiastic teachers, you want your students to see the connections between important science concepts so they can grasp how the world works now—and maybe even make it work better in the future. But how exactly do you help them learn and apply these core ideas? Just as its subtitle says, this important book aims to reshape your approach to teaching and your students’ way of learning. Building on the foundation provided by A Framework for K–12 Science Education, which informed the development of the Next Generation Science Standards, the book’s four sections cover these broad areas: 1. Physical science core ideas explain phenomena as diverse as why water freezes and how information can be sent around the world wirelessly. 2. Life science core ideas explore phenomena such as why children look similar but not identical to their parents and how human behavior affects global ecosystems. 3. Earth and space sciences core ideas focus on complex interactions in the Earth system and examine phenomena as varied as the big bang and global climate change. 4. Engineering, technology, and applications of science core ideas highlight engineering design and how it can contribute innovative solutions to society’s problems. Disciplinary Core Ideas can make your science lessons more coherent and memorable, regardless of what subject matter you cover and what grade you teach. Think of it as a conceptual tool kit you can use to help your students learn important and useful science now—and continue learning throughout their lives.

This volume presents current thoughts, research, and findings that were presented at a summit focusing on energy as a cross-cutting concept in education, involving scientists, science education researchers and science educators from across the world. The chapters cover four key questions: what should students know about energy, what can we learn from research on teaching and learning about energy, what are the challenges we are currently facing in teaching students this knowledge, and what needs be done to meet these challenges in the future? Energy is one of the most important ideas in all of science and it is useful for predicting and explaining phenomena within every scientific discipline. The challenge for teachers is to respond to recent policies requiring them to teach not only about energy as a disciplinary idea but also about energy as an analytical framework that cuts across disciplines. Teaching energy as a crosscutting concept can equip a new generation of scientists and engineers to think about the latest cross-disciplinary problems, and it requires a new approach to the idea of energy. This book examines the latest challenges of K-12 teaching about energy, including how a comprehensive understanding of energy can be developed. The authors present innovative strategies for learning and teaching about energy, revealing overlapping and diverging views from scientists and science educators. The reader will discover investigations into the learning progression of energy, how understanding of energy can be examined, and proposals for future directions for work in this arena. Science teachers and educators, science education researchers and scientists themselves will all find the discussions and research presented in this book engaging and informative.

This volume presents current thoughts, research, and findings that were presented at a summit focusing on energy as a cross-cutting concept in education, involving scientists, science education researchers and science educators from across the world. The chapters cover four key questions: what should students know about energy, what can we learn from research on teaching and learning about energy, what are the challenges we are currently facing in teaching students this knowledge, and what needs be done to meet these challenges in the future?
Energy is one of the most important ideas in all of science and it is useful for predicting and explaining phenomena within every scientific discipline. The challenge for teachers is to respond to recent policies requiring them to teach not only about energy as a disciplinary idea but also about energy as an analytical framework that cuts across disciplines. Teaching energy as a crosscutting concept can equip a new generation of scientists and engineers to think about the latest cross-disciplinary problems, and it requires a new approach to the idea of energy.
This book examines the latest challenges of K-12 teaching about energy, including how a comprehensive understanding of energy can be developed. The authors present innovative strategies for learning and teaching about energy, revealing overlapping and diverging views from scientists and science educators. The reader will discover investigations into the learning progression of energy, how understanding of energy can be examined, and proposals for future directions for work in this arena.
Science teachers and educators, science education researchers and scientists themselves will all find the discussions and research presented in this book engaging and informative.

Education has traditionally studied the world by bringing it into the classroom. This can result in situated learning that appears to students to have no relevance outside the classroom. Students acquire inert, decontextualized knowledge that they cannot apply to real problems. The obvious solution to this shortcoming is to reverse the situation and bring the classroom to the phenomena: to learn in a rich, real-world context. The problem with the real world is that it is complex and filled with interactions that are hard to sort out. The editors and authors believe that the right tools might help students with this sorting process and result in learning in rich contexts. This book is an account of a series of experiments designed to explore the validity of this insight.

An innovative, internationally developed system to help advance science learning and instruction for high school students This book tells the story of a $3.6 million research project funded by the National Science Foundation aimed at increasing scientific literacy and addressing global concerns of declining science engagement. Studying dozens of classrooms across the United States and Finland, this international team combines large-scale studies with intensive interviews from teachers and students to examine how to transform science education. Written for teachers, parents, policymakers, and researchers, this book offers solutions for matching science learning and instruction with newly recommended twenty-first-century standards. Included are science activities that engage and inspire students; sample lesson plans; and approaches for measuring science engagement and encouragement of three-dimensional learning.

Science Education Through Multiple Literacies explores how the use of project-based learning in elementary science education fosters a lifelong scientific mindset in students. The book provides educators with the teaching practices to help students develop an overall science literacy that aligns with Next Generation Science Standards. Editors Joseph Krajcik and Barbara Schneider and the book’s contributors offer a comprehensive overview of the Multiple Literacies in Project-Based Learning (ML-PBL) approach to science learning, which interweaves scientific ideas and practices, language literacy, and mathematical thinking. ML-PBL supports the teaching of science by paralleling what scientists do: it engages students and their teachers in investigating real-world questions, constructing models, and using evidence to evaluate claims. The book presents compelling case studies of ML-PBL, how teachers use them, and how the teachers’ enactment transforms the classroom into an environment that builds and supports academic and student SEL. Representing both urban and suburban schools, the case studies include classroom observations, student and teacher interviews, and student artifacts to illustrate how to make science relevant in students’ lives. Krajcik and Schneider note that classroom enactment of ML-PBL requires intentional instructional practices and new ways of thinking about what it means to learn. Easing this challenge, they equip elementary science teachers with curricular resources including high-quality instructional materials, professional-learning exercises, and formative assessments. Science Education Through Multiple Literacies provides the necessary elements to transform science teaching and learning so that students learn the skills to navigate with confidence through our complex world.