This book explores science education as a learning continuum across all years of schooling from Foundation to Year 12. It seeks to build pedagogical and content expertise by providing both a level of support and challenge for all teachers based on current research and best practice. The text considers key issues including: what the learner brings to the science classroom; what primary and secondary teachers can learn from each other; the constructivist perspective and its value in learning science; context-based science education; the structure of the Australian curriculum and science education policy; teacher identity; the nature of scientific knowledge; principles of assessment and understanding the role of ICT in science teaching and learning. Featuring case studies and practical examples in each chapter, this book provides pre-service teachers with the understanding and tools to ensure their students are engaged and inspired in science education throughout their school years.

In this ground-breaking book science education is explored as a learning continuum across all years of schooling from Foundation to Year 12. The expert authors, members of Monash University's Science Education Research Group, seek to build pedagogical and content expertise by providing both a level of support and challenge for all teachers based on current research and best practice. The text considers key issues including: what the learner brings to the science classroom; what primary and secondary teachers can learn from each other; the constructivist perspective and its value in learning science; context-based science education; the structure of the Australian curriculum and science education policy; teacher identity; the nature of scientific knowledge; principles of assessment and understanding the role of ICT in science teaching and learning. Featuring case studies and practical examples in each chapter, this book provides pre-service teachers with the understanding and tools to ensure their students are engaged and inspired in science education throughout their school years.

In 2007, the Monash-Kings College London International Centre for the Study of Science and Mathematics Curriculum edited a book called The Re-emergence of Values in Science Education. This book reflects on how values have been considered since this original publication, particularly in terms of socio-cultural, economic and political factors that have impacted broadly on science, technology and society, and more specifically on informal and formal science curricula. Hence, the title of this book has been framed as Values in Science Education: The shifting sands. As in the first book, this collection focuses on values that are centrally associated with science and its teaching, and not the more general notion of values such as cooperation or teamwork that are also important values in current curricula. Such values have indeed become more of a focus in science education. This may be a response to the changing global context, where technological changes have been rapid and accelerating. In such complex and risky environments, it is our guiding principles that become the important mainstays of our decisions and practices. In terms of science education, what is becoming clearer is that traditional content and traditional science and scientific methods are not enough for science and hence science education to meet such challenges. While shifts in values in science education continue, tensions remain in curriculum development and implementation, as evidenced by the continued diversity of views about what and whose values matter most.

In 2007, the Monash-Kings College London International Centre for the Study of Science and Mathematics Curriculum edited a book called The Re-emergence of Values in Science Education. This book reflects on how values have been considered since this original publication, particularly in terms of socio-cultural, economic and political factors that have impacted broadly on science, technology and society, and more specifically on informal and formal science curricula. Hence, the title of this book has been framed as Values in Science Education: The shifting sands. As in the first book, this collection focuses on values that are centrally associated with science and its teaching, and not the more general notion of values such as cooperation or teamwork that are also important values in current curricula. Such values have indeed become more of a focus in science education. This may be a response to the changing global context, where technological changes have been rapid and accelerating. In such complex and risky environments, it is our guiding principles that become the important mainstays of our decisions and practices. In terms of science education, what is becoming clearer is that traditional content and traditional science and scientific methods are not enough for science and hence science education to meet such challenges. While shifts in values in science education continue, tensions remain in curriculum development and implementation, as evidenced by the continued diversity of views about what and whose values matter most.

This book presents research involving learning opportunities that are afforded to learners of science when the focus is on linking the formal and informal science education sectors. It uses the metaphor of a "landscape" as it emphasises how the authors see the possible movement within a landscape that is inclusive of formal, informal and free-choice opportunities. The book explores opportunities to change formal school science education via perspectives and achievements from the informal and free-choice science education sector within the wider lifelong, life-wide education landscape. Additionally it explores how science learning that occurs in a more inclusive landscape can demonstrate the potential power of these opportunities to address issues of relevance and engagement that currently plague the learning of science in school settings. Combining specific contexts, case studies and more general examples, the book examines the science learning landscapes by means of the lens of an ecosystem and the case of the Synergies longitudinal research project. It explores the relationships between school and museum, and relates the lessons learned through encounters with a narwhal. It discusses science communication, school-community partnerships, socioscientific issues, outreach education, digital platforms and the notion of a learning ecology.

This volume considers the future of science learning - what is being learned and how it is being learned - in formal and informal contexts for science education. To do this, the book explores major contemporary shifts in the forms of science that could or should be learned in the next 20 years, what forms of learning of that science should occur, and how that learning happens, including from the perspective of learners. In particular, this volume addresses shifts in the forms of science that are researched and taught post-school - emerging sciences, new sciences that are new integrations, "futures science", and increases in the complexity and multidisciplinarity of science, including a multidisciplinarity that embraces ways of knowing beyond science. A central aspect of this in terms of the future of learning science is the urgent need to engage students, including their non-cognitive, affective dimensions, both for an educated citizenry and for a productive response to the ubiquitous concerns about future demand for science-based professionals. Another central issue is the actual impact of ICT on science learning and teaching, including shifts in how students use mobile technology to learn science.

This volume considers the future of science learning - what is being learned and how it is being learned - in formal and informal contexts for science education. To do this, the book explores major contemporary shifts in the forms of science that could or should be learned in the next 20 years, what forms of learning of that science should occur, and how that learning happens, including from the perspective of learners. In particular, this volume addresses shifts in the forms of science that are researched and taught post-school - emerging sciences, new sciences that are new integrations, "futures science", and increases in the complexity and multidisciplinarity of science, including a multidisciplinarity that embraces ways of knowing beyond science. A central aspect of this in terms of the future of learning science is the urgent need to engage students, including their non-cognitive, affective dimensions, both for an educated citizenry and for a productive response to the ubiquitous concerns about future demand for science-based professionals. Another central issue is the actual impact of ICT on science learning and teaching, including shifts in how students use mobile technology to learn science.

Assessment is a fundamental issue in research in science education, in curriculum development and implementation in science education as well as in science teaching and learning. This book takes a broad and deep view of research involving assessment in science education, across contexts and cultures (from whole countries to individual classrooms) and across forms and purposes (from assessment in the service of student learning to policy implications of system wide assessment). It examines the relationships between assessment, measurement and evaluation; explores assessment philosophies and practices in relation to curriculum and scientific literacy/learning; and details the relationships between assessment and science education policy. The third in a series, Valuing Assessment in Science Education has chapters from a range of international scholars from across the globe and staff from Monash University, King's College London and University of Waikato. The two previous books in the series examined research relevant to the re-emergence of values in science education and teaching across the spectrum of science education as well as across cultural contexts through the professional knowledge of science teaching. This third book now moves to examine different aspects of generating understanding about what science is learnt, how it is learnt, and how it is valued. Valuing Assessment in Science Education will appeal to all those with some engagement with and/or use of research in science education, including research students, academics, curriculum development agencies, assessment authorities, and policy makers. It will also be of interest to all classroom science teachers who seek to keep abreast of the latest research and development and thinking in their area of professional concern.

Over the past twenty years, much has been written about the knowledge bases thought necessary to teach science. Shulman has outlined seven knowledge domains needed for teaching, and others, such as Tamir, have proposed somewhat similar domains of knowledge, specifically for science teachers. Aspects of this knowledge have changed because of shifts in curriculum thinking, and the current trends in science education have seen a sharp increase in the significance of the knowledge bases. The development of a standards-based approach to the quality of science teaching has become common in the Western world, and phrases such as "evidence-based practice" have been tossed around in the attempt to "measure" such quality. The Professional Knowledge Base of Science Teaching explores the knowledge bases considered necessary for science teaching. It brings together a number of researchers who have worked with science teachers, and they address what constitutes evidence of high quality science teaching, on what basis such evidence can be judged, and how such evidence reflects the knowledge basis of the modern day professional science teacher. This is the second book produced from the Monash University- King's College London International Centre for the Study of Science and Mathematics Curriculum. The first book presented a big picture of what science education might be like if values once again become central while this book explores what classroom practices may look like based on such a big picture.

Assessment is a fundamental issue in research in science education, in curriculum development and implementation in science education as well as in science teaching and learning. This book takes a broad and deep view of research involving assessment in science education, across contexts and cultures (from whole countries to individual classrooms) and across forms and purposes (from assessment in the service of student learning to policy implications of system wide assessment). It examines the relationships between assessment, measurement and evaluation; explores assessment philosophies and practices in relation to curriculum and scientific literacy/learning; and details the relationships between assessment and science education policy. The third in a series, Valuing Assessment in Science Education has chapters from a range of international scholars from across the globe and staff from Monash University, King's College London and University of Waikato. The two previous books in the series examined research relevant to the re-emergence of values in science education and teaching across the spectrum of science education as well as across cultural contexts through the professional knowledge of science teaching. This third book now moves to examine different aspects of generating understanding about what science is learnt, how it is learnt, and how it is valued. Valuing Assessment in Science Education will appeal to all those with some engagement with and/or use of research in science education, including research students, academics, curriculum development agencies, assessment authorities, and policy makers. It will also be of interest to all classroom science teachers who seek to keep abreast of the latest research and development and thinking in their area of professional concern.

Over the past twenty years, much has been written about the knowledge bases thought necessary to teach science. Shulman has outlined seven knowledge domains needed for teaching, and others, such as Tamir, have proposed somewhat similar domains of knowledge, specifically for science teachers. Aspects of this knowledge have changed because of shifts in curriculum thinking, and the current trends in science education have seen a sharp increase in the significance of the knowledge bases. The development of a standards-based approach to the quality of science teaching has become common in the Western world, and phrases such as "evidence-based practice" have been tossed around in the attempt to "measure" such quality. The Professional Knowledge Base of Science Teaching explores the knowledge bases considered necessary for science teaching. It brings together a number of researchers who have worked with science teachers, and they address what constitutes evidence of high quality science teaching, on what basis such evidence can be judged, and how such evidence reflects the knowledge basis of the modern day professional science teacher. This is the second book produced from the Monash University- King's College London International Centre for the Study of Science and Mathematics Curriculum. The first book presented a big picture of what science education might be like if values once again become central while this book explores what classroom practices may look like based on such a big picture.

How do we enable young people to imagine themselves as the next generation of STEM professionals? How do we do this in a way that engages the desire to learn and explore? In Australia, there is increasing concern at the declining participation in advanced-level school mathematics and physical sciences; fewer students electing to study STEM programs at university; and, evidence of declining performance of Australian students on international comparative tests in mathematics and science. This timely book highlights the need to reconceptualise Maths and Science Teacher Education Programs (ReMSTEP) in order to revitalise maths and science teaching approaches within primary and secondary schools. Through a series of seven `innovations', such as offering maths and science specialisations within primary pre-service teaching programs, or creating opportunities to connect scientists and mathematicians with both pre-service teachers and practitioners in developing activities for school contexts, ReMSTEP recognises that teacher graduates are powerful change agents for making maths and science curricula more engaging, challenging and relevant for primary and secondary students. This substantively researched text, based on ReMSTEP's extensive trialling and exhaustive consultation with researchers and practitioners alike, enriches the debate on the educational relevance of maths and science, and is a crucial reference for educational decision-makers, lecturers and pre-service teachers, and school leaders. Part A examines the challenges around science and maths education. Part B explores, through case studies, the seven ReMSTEP innovations around which the activities were organised. Part C provides an overview of the impacts of the innovations and explores the implications of the findings.