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Open-ended inquiry activities from a constructionist perspective for young children. Basic processes include: observing, classifying, communicating, measuring, predicting, and inferring,
With the view that children are capable young scientists, authors encourage science teaching in ways that nurture students' curiosity about how the natural world works including research-based approaches to support all K-5 children constructing scientific explanations via talk and writing. Grounded in NSF-funded research, this book/DVD provides K-5 teachers with a framework for explanation (Claim, Evidence, Reasoning) that they can use to organize everything from planning to instructional strategies and from scaffolds to assessment. Because the framework addresses not only having students learn scientific explanations but also construct them from evidence and evaluate them, it is considered to build upon the new NRC framework for K-12 science education, the national standards, and reform documents in science education, as well as national standards in literacy around argumentation and persuasion, including the Common Core Standards for English Language Arts (Common Core State Standards Initiative, 2010).The chapters guide teachers step by step through presenting the framework for students, identifying opportunities to incorporate scientific explanation into lessons, providing curricular scaffolds (that fade over time) to support all students including ELLs and students with special needs, developing scientific explanation assessment tasks, and using the information from assessment tasks to inform instruction.
Giving early years practitioners and students the confidence to effectively support scientific exploration and investigation with young children, this book explains the science behind young children's knowledge and understanding of the world. Linking theory to good early years practice, the emphasis throughout the book is on recognizing young children as competent, creative thinkers and building on their ideas. The reader is encouraged to think carefully about the role of the adult in supporting child-initiated learning and discovery by providing open ended resources, asking productive questions and observing carefully. The authors provide essential background information for all the key areas of scientific knowledge supported by practical ideas suitable for babies, toddlers and children aged 3 to 5 years. For each of these ideas, practice and theory are linked by highlighting the skills, attitudes and dispositions to observe and the questions to ask to challenge young children's thinking and plan for the next stages in their learning. Chapters cover: - the place of science in early years curricula in the UK - the processes of science and the role of the adult in supporting young children's scientific learning - using open ended resources to create a science-rich environment - essential background knowledge, covering all areas of early years science - ideas to use as starting points for exploration and investigation, indoors and outdoors - pointers for observational assessment and planning - suppliers of resources and equipment By making clear links to practice, and providing ideas to use with babies and toddlers as well as with 3-5 year old children, this book enables the reader to fully exploit the potential for exploration and investigation in any early years setting. Pat Brunton and Linda Thornton are both Education Consultants based in Cheltenham. They run their own training and consultancy company alc associates, and edit Early Years Update.
Stretch children's minds and imaginations - and help them meet the standards - with dozens and dozens of fresh activities for your classroom learning centers. each of the five sections of this treasury is devoted to a different learning center - literacy, math, dramatic play, blocks, and art. Within each section, you'll find delightful ideas and projects that integrate math, literacy, science, and more. These flexible, cross-curricular activities are designed to engage children, foster independent learning, and develop essential skills. Create learning center magig in your classroom each and every day!--
An examination of children’s causal reasoning capacities and how those capacities serve as the foundation of their scientific thinking. Young children have remarkable capacities for causal reasoning, which are part of the foundation of their scientific thinking abilities. In Constructing Science, Deena Weisberg and David Sobel trace the ways that young children’s sophisticated causal reasoning abilities combine with other cognitive, metacognitive, and social factors to develop into a more mature set of scientific thinking abilities. Conceptualizing scientific thinking as the suite of skills that allows people to generate hypotheses, solve problems, and explain aspects of the world, Weisberg and Sobel argue that understanding how this capacity develops can offer insights into how we can become a more scientifically literate society. Investigating the development of causal reasoning and how it sets the stage for scientific thinking in the elementary school years and beyond, Weisberg and Sobel outline a framework for understanding how children represent and learn causal knowledge and identify key variables that differ between causal reasoning and scientific thinking. They present empirical studies suggesting ways to bridge the gap between causal reasoning and scientific thinking, focusing on two factors: contextualization and metacognitive thinking abilities. Finally, they examine children’s explicit understanding of such concepts as science, learning, play, and teaching.
Constructing Representations to Learn in Science Current research into student learning in science has shifted attention from the traditional cognitivist perspectives of conceptual change to socio-cultural and semiotic perspectives that characterize learning in terms of induction into disciplinary literacy practices. This book builds on recent interest in the role of representations in learning to argue for a pedagogical practice based on students actively generating and exploring representations. The book describes a sustained inquiry in which the authors worked with primary and secondary teachers of science, on key topics identified as problematic in the research literature. Data from classroom video, teacher interviews and student artifacts were used to develop and validate a set of pedagogical principles and explore student learning and teacher change issues. The authors argue the theoretical and practical case for a representational focus. The pedagogical approach is illustrated and explored in terms of the role of representation to support quality student learning in science. Separate chapters address the implications of this perspective and practice for structuring sequences around different concepts, reasoning and inquiry in science, models and model based reasoning, the nature of concepts and learning, teacher change, and assessment. The authors argue that this representational focus leads to significantly enhanced student learning, and has the effect of offering new and productive perspectives and approaches for a number of contemporary strands of thinking in science education including conceptual change, inquiry, scientific literacy, and a focus on the epistemic nature of science.
Creating Curriculum in Early Childhood explores the backward design model of curriculum development, equipping readers with the tools and methods they need to effectively apply backward design in the early childhood classroom. Clear yet comprehensive chapters walk new and veteran educators through an effective method for curriculum design that promotes meeting standards through intentional teaching while engaging children in developmentally appropriate, interest-based education focused on big ideas and conceptual understanding. Featuring desired results, assessment methods, and teaching techniques specific to birth to age eight, this critical guide also includes practical tips for educators new to the method. Designed to help students and practitioners alike, this powerful textbook combines early childhood philosophy and developmental research with highly practical descriptions, rationales, and examples for developing curricular units using backward design.
In Constructing Policy Change, Linda A. White examines the expansion of early childhood education and care (ECEC) policies and programs in liberal welfare states, including Australia, Canada, New Zealand, the UK, and the USA. In the first part of the book, the author investigates the sources of policy ideas that triggered ECEC changes in various national contexts. This is followed by a close analysis of cross-national variation in the implementation of ECEC policy in Canada and the USA. White argues that the primary mechanisms for policy change are grounded in policy investment logics as well as cultural logics: that is, shifts in public sentiments and government beliefs about the value of ECEC policies and programs are rooted in both evidence-based arguments and in principled beliefs about the policy. A rich, nuanced examination of the reasons motivating ECEC policy expansion and adoption in different countries, Constructing Policy Change is a corrective to the comparative welfare state literature that focuses on political interest alone.
The book synergizes research on number across two disciplines—mathematics education and psychology. The underlying problem the book addresses is how the brain constructs number. The opening chapter frames the problem in terms of children’s activity, including mental and physical actions. Subsequent chapters are organized into sections that address specific domains of number: natural numbers, fractions, and integers. Chapters within each section address ways that children build upon biological primitives (e.g., subitizing) and prior constructs (e.g., counting sequences) to construct number. The book relies on co-authored chapters and commentaries at the end of each section to create dialogue between junior faculty and senior researchers, as well as between psychologists and mathematics educators. The final chapter brings this work together around the framework of children’s activity and additional themes that arise in the collective work. The book is aimed to appeal to mathematics educators, mathematics teacher educators, mathematics education researchers, educational psychologists, cognitive psychologists, and developmental psychologists.
This third edition has been substantially updated to include current research, written by a team of respected science education researchers. It complements the Australian Early Years Learning Framework and the Australian Curriculum: Science. Concepts are brought to life through case studies, practical tasks and activity plans.