This special issue works toward refining the understanding of a construct that has had a name for nearly 30 years and has been used by educators of all stripes for centuries. The introduction lays the groundwork for discussing the issues addressed throughout. Each of the papers address different aspects of a similar problem: How can we conceptualize, design, and assess the effects of scaffolding when it is implemented in a complex classroom system? The first article addresses a core problem in conceptualizing scaffolding: What are the specific goals of scaffolding provided in software tools? The next paper extends this consideration of how scaffolding mechanisms can complement each other and explores issues having to do with the complex settings in which scaffolding is used. A framework which synthesizes theoretical and design work done in cognitive science, psychology, educational technology, science education, and the learning sciences over the last three decades is the topic of the third paper. The final article presents a new method for analyzing the effects of scaffolding. This special issues closes with commentary covering different components of a definition of scaffolding, including the "what, why, and how" of scaffolding.

Grounded in empirical research, this book offers concrete pathways to direct attention towards elementary science teaching that privileges sensemaking, rather than isolated activities and vocabulary. Outlining a clear vision for this shift using research-backed tools, pedagogies, and practices to support teacher learning and development, this edited volume reveals how teachers can best engage in teaching that supports meaningful learning and understanding in elementary science classrooms. Divided into three sections, this book demonstrates the skills, knowledge bases, and research-driven practices necessary to make a fundamental shift towards a focus on students' ideas and reasoning, and covers topics such as: An introduction to sensemaking in elementary science; Positioning students at the center of sensemaking; Planning and enacting investigation-based science discussions; Designing a practice-based elementary teacher education program; Reflections on science teacher education and professional development for reform-based elementary science. In line with current reform efforts, including the Next Generation Science Standards (NGSS), Sensemaking in Elementary Science is the perfect resource for graduate students and researchers in science education, elementary education, teacher education, and STEM education looking to explore effective practice, approaches, and development within the elementary science classroom.

Grounded in empirical research, this book offers concrete pathways to direct attention towards elementary science teaching that privileges sensemaking, rather than isolated activities and vocabulary. Outlining a clear vision for this shift using research-backed tools, pedagogies, and practices to support teacher learning and development, this edited volume reveals how teachers can best engage in teaching that supports meaningful learning and understanding in elementary science classrooms. Divided into three sections, this book demonstrates the skills, knowledge bases, and research-driven practices necessary to make a fundamental shift towards a focus on students' ideas and reasoning, and covers topics such as: An introduction to sensemaking in elementary science; Positioning students at the center of sensemaking; Planning and enacting investigation-based science discussions; Designing a practice-based elementary teacher education program; Reflections on science teacher education and professional development for reform-based elementary science. In line with current reform efforts, including the Next Generation Science Standards (NGSS), Sensemaking in Elementary Science is the perfect resource for graduate students and researchers in science education, elementary education, teacher education, and STEM education looking to explore effective practice, approaches, and development within the elementary science classroom.

Internet Environments for Science Education synthesizes 25 years of research to identify effective, technology-enhanced ways to convert students into lifelong science learners--one inquiry project at a time. It offers design principles for development of innovations; features tested, customizable inquiry projects that students, teachers, and professional developers can enact and refine; and introduces new methods and assessments to investigate the impact of technology on inquiry learning. The methodology--design-based research studies--enables investigators to capture the impact of innovations in the complex, inertia-laden educational enterprise and to use these findings to improve the innovation. The approach--technology-enhanced inquiry--takes advantage of global, networked information resources, sociocognitive research, and advances in technology combined in responsive learning environments. Internet Environments for Science Education advocates leveraging inquiry and technology to reform the full spectrum of science education activities--including instruction, curriculum, policy, professional development, and assessment. The book offers: *the knowledge integration perspective on learning, featuring the interpretive, cultural, and deliberate natures of the learner; *the scaffolded knowledge integration framework on instruction summarized in meta-principles and pragmatic principles for design of inquiry instruction; *a series of learning environments, including the Computer as Learning Partner (CLP), the Knowledge Integration Environment (KIE), and the Web-based Inquiry Science Environment (WISE) that designers can use to create new inquiry projects, customize existing projects, or inspire thinking about other learning environments; *curriculum design patterns for inquiry projects describing activity sequences to promote critique, debate, design, and investigation in science; *a partnership model establishing activity structures for teachers, pedagogical researchers, discipline experts, and technologists to jointly design and refine inquiry instruction; *a professional development model involving mentoring by an expert teacher; *projects about contemporary controversy enabling students to explore the nature of science; *a customization process guiding teachers to adapt inquiry projects to their own students, geographical characteristics, curriculum framework, and personal goals; and *a Web site providing additional links, resources, and community tools at www.InternetScienceEducation.org

Internet Environments for Science Education synthesizes 25 years of research to identify effective, technology-enhanced ways to convert students into lifelong science learners--one inquiry project at a time. It offers design principles for development of innovations; features tested, customizable inquiry projects that students, teachers, and professional developers can enact and refine; and introduces new methods and assessments to investigate the impact of technology on inquiry learning. The methodology--design-based research studies--enables investigators to capture the impact of innovations in the complex, inertia-laden educational enterprise and to use these findings to improve the innovation. The approach--technology-enhanced inquiry--takes advantage of global, networked information resources, sociocognitive research, and advances in technology combined in responsive learning environments. Internet Environments for Science Education advocates leveraging inquiry and technology to reform the full spectrum of science education activities--including instruction, curriculum, policy, professional development, and assessment. The book offers: *the knowledge integration perspective on learning, featuring the interpretive, cultural, and deliberate natures of the learner; *the scaffolded knowledge integration framework on instruction summarized in meta-principles and pragmatic principles for design of inquiry instruction; *a series of learning environments, including the Computer as Learning Partner (CLP), the Knowledge Integration Environment (KIE), and the Web-based Inquiry Science Environment (WISE) that designers can use to create new inquiry projects, customize existing projects, or inspire thinking about other learning environments; *curriculum design patterns for inquiry projects describing activity sequences to promote critique, debate, design, and investigation in science; *a partnership model establishing activity structures for teachers, pedagogical researchers, discipline experts, and technologists to jointly design and refine inquiry instruction; *a professional development model involving mentoring by an expert teacher; *projects about contemporary controversy enabling students to explore the nature of science; *a customization process guiding teachers to adapt inquiry projects to their own students, geographical characteristics, curriculum framework, and personal goals; and *a Web site providing additional links, resources, and community tools at www.InternetScienceEducation.org