From the author of Neuromyths, a revolutionary look at teaching and learning via the logical pathways of the brain. A review of the research on brain networks reveals, surprisingly, that there are just five basic pillars through which all learning takes place: Symbols, Patterns, Order, Categories, and Relationships. Dr. Tokuhama-Espinosa proposes that redesigning school curriculum around these five pillars—whether to augment or replace traditional subject categories—could enable students to develop the transdisciplinary problem-solving skills that are often touted as the ultimate goal of education. Heralding a potential paradigm shift in education, Five Pillars of the Mind explores how aligning instruction with the brain's natural design might just be the key to improving students' learning outcomes.
Mind, Brain, and Education science is a very young field, though it has roots in thousands of years of academic reflection. This book is a brief but critical look into the key turning points in the field’s evolution and the existing initiatives in order to project its future directions. It draws on information from all major branches of the learning sciences, including philosophy and history, and more modern constructs such as cognitive psychology and neuroscience. First and foremost, it is a textbook for early graduate training programs in Mind, Brain, and Education science and Educational Neuroscience and those who would like to have Learning Sciences as their main area of study, but the book will also serve as an introduction for those educational policymakers who would like to ground decision-making in evidence from the Learning Sciences, and neuroscientists who need to have knowledge about mind and education.
Young Investigators has been expanded to guide today’s teachers through the process of conducting meaningful investigations with young children. This fourth edition of the bestseller begins with a new chapter, “How Children Really Learn,” which summarizes insights from mind-brain education research, showing how experiences firmly rooted in children’s curiosity and interest build intellectual capacity. The book then introduces the Project Approach with step-by-step guidance for incorporating child initiation and direction into curriculum while simultaneously addressing content standards. A new focus on critical Teacher Decision Points uses fresh-from-the-classroom examples to show how teachers think through project work. The emphasis on STEM experiences has been expanded to include STEAM through a new chapter, “The Role of Project Work in the Arts” This book makes project-based learning possible with the youngest children (toddlers through 2nd grade) who are not yet proficient in reading and writing, but capable of deep, focused thinking. Throughout, readers empathize with teachers’ concerns, witness how they find solutions to challenges, and feel the excitement of children during project work. Young Investigators is appropriate for teachers new to using the Project Approach, as well as for those who already have experience. Book Features: Examples of projects from child care centers and preschool, K–2, and special education classrooms.Instructions for incorporating standards and STEAM skills into project work.A variety of experiences to help children connect to the natural world. Toddler projects that reflect knowledge from recent mind-brain research.Tools for integrating required curriculum goals and for assessing achievement.A Teacher Project Planning Journal that leads teachers through the major decision points of project work.Full-color photographs of children engaged with projects. A study guide for pre- and inservice teachers (available at www.tcpress.com).
This practical resource draws on the best of neuroscience to inform decision-making about digital learning. We live in unprecedented times that have pushed schools to make many decisions that have been postponed for years. For the first time since the inception of public education, teachers have been invited to redesign the learning landscape by integrating an intelligent selection of digital educational resources and changing pedagogical approaches based on information from the learning sciences. This handbook will help teachers make the most of this opportunity by showing them how to use digital tools to differentiate learning, employ alternative options to standardized testing, personalize learning, prioritize social-emotional skills, and inspire students to think more critically. The author identifies some gems in quality teaching that are amplified in online contexts, including 40 evidence-informed pedagogies from the learning sciences. This book will help all educators move online teaching and learning to new levels of confidence and success. Book Features: Provides quick references to key planning tools like decision-trees, graphics, app recommendations, and step-by-step directions to help teachers create their own online learning courses.Guides teachers through a 12-step model for instructional design that meets both national and international standards.Shows educators how to use an all-new Digital Resource Taxonomy to select resources, and how to research and keep them up to date.Explains why good instructional design and educational technology are complementary with best practices in learning sciences like Mind, Brain, and Education Science.Shares ways teachers can leverage technology to create more time for the personalized aspects of learning. Shows educators how to design online courses with tools that let all students begin at their own starting points and how to differentiate homework.Offers evidence-informed pedagogies to make online intimate and authentic for students.
This book presents a novel conceptualisation of universal information processing systems based on studies of environmental interaction in both biological and non-biological systems. This conceptualisation is used to demonstrate how a single overarching framework can be applied to the investigation of human learning and memory by considering matter and energy pathways and their connections. In taking a stance based on everyday interactions, as well as on scientific practices, the conceptualisation is used to consider educational theories and practices, exemplified by the widely cited cognitive load theory. In linking these theories and practices more closely to scientific thinking, the book embraces an holistic approach to informational interactions, not limited to conceptualisations of pattern, signal or meaning. The book offers educational researchers and educators an opportunity to re-think their approach to instruction – to take all facets of student learning environments into account in increasing human knowledge, skills and experiences across society.
A perennial bestseller since 1997, this updated tenth edition of Understanding Research Methods provides a detailed overview of all the important concepts traditionally covered in a research methods class. It covers the principles of both qualitative and quantitative research, and how to interpret statistics without computations, so is suitable for all students regardless of their math background. The book is organized so that each concept is treated independently and can be used in any order without resulting in gaps in knowledge—allowing it to be easily and precisely adapted to any course. It uses lively examples on contemporary topics to stimulate students’ interest, and engages them by showing the relevance of research methods to their everyday lives. Numerous case studies and end-of-section exercises help students master the material and encourage classroom discussion. The text is divided into short, independent topic sections, making it easy for you to adapt the material to your own teaching needs and customize assignments to the aspect of qualitative or quantitative methods under study—helping to improve students’ comprehension and retention of difficult concepts. Additional online PowerPoint slides and test bank questions make this a complete resource for introducing students to research methods. New to this edition: New topic section on design decisions in research Additional material on production of knowledge and research methods Significant development of material on ethical considerations in research Fresh and contemporary examples from a wide variety of real, published research Topic-specific exercises at the end of each section now include suggestions for further steps researchers can take as they build their research project.
This book focuses on some important aspects of Physics Education: the role of metaphors in Physics teaching and learning, the connections between Physics and Mathematics, the interaction of young children with Physics at the primary level, and recent developments in teacher education in the USA. Contributors present their research related to: • Preparing teachers for TPACK (technological, pedagogical, and content knowledge) and laboratory work. • Developing and evaluating teacher PCK (pedagogical content knowledge) in Quantum Mechanics. • In-service Physics teacher education for early childhood and primary levels. • Pre-service Physics teacher education at all levels. • In-service Physics teacher professional learning for second and higher-level education. Chapters in this book inevitably look into how Physics teacher education is organized in different countries. Suggestions are offered for possible ways of supporting Physics teachers’ learning. An emphasis is made on the much-needed measurements of the effectiveness of different teaching strategies that improve teaching for learning. All this should help professionals, researchers, and pre-service, as well as in-service teachers to get acquainted with the most recent research contributions in the field.
Embodied cognition is one of the foremost areas of study and research in philosophy of mind, philosophy of psychology, and cognitive science. The Routledge Handbook of Embodied Cognition is an outstanding guide and reference source to the key topics and debates in this exciting subject and essential reading for any student and scholar of philosophy of mind and cognitive science. Extensively revised and enlarged for this second edition, the Handbook comprises 42 chapters by an international team of expert contributors and is divided into ten parts: Historical Underpinnings Perspectives on Embodied Cognition Embodied Cognition and Predictive Processing Perception Language Reasoning and Education Virtual Reality Social and Moral Cognition and Emotion Action and Memory Reflections on Embodied Cognition The early chapters of the Handbook cover empirical and philosophical foundations of embodied cognition, focusing on Gibsonian and phenomenological approaches. Subsequent chapters cover additional, important themes common to work in embodied cognition, including embedded, extended, and enactive cognition as well as chapters on empirical research in perception, language, reasoning, social and moral cognition, emotion, consciousness, memory, and learning and development. For the second edition many existing chapters have been revised and seven new chapters added on: AI and robotics, predictive processing, second-language learning, animal cognition, sport psychology, sense of self, and critiques of embodied cognition, bringing the Handbook fully up to date with current research and debate.
Providing a complete and contemporary overview of the evolving and fascinating world of work, this new edition of Work and Organizational Psychology is the perfect textbook, outlining not only key theoretical ideas, but how they relate to the role of psychologists advising today’s organizations. Integrating the fields of human resource management and organizational behaviour, the text begins with a chapter to give the reader an insight into the domain of work and organizational psychology, the development of the field of work and organizational psychology, tasks and competencies of organizational and work psychologists, and careers in work and organizational psychology. The remainder of the book is divided into thirteen chapters which address the core areas of work and organizational psychology. The book is supported by a range of pedagogical features, spotlighting issues of theoretical, ethical, or contemporary interest, whilst also enabling students to engage in active learning.
Neuroscience contributes to the basic understanding of the neural mechanisms underlying human development and learning. Educational neuroscience is an interdisciplinary research field that seeks to translate research findings on neural mechanisms of learning to educational practice and policy and to understand the effects of education on the brain. It is an emerging multidisciplinary field where the aim is to link basic research in neuroscience, psychology, and cognitive science, with educational technology. Educational neuroscience is often associated with the ‘science’ of learning and encompasses a broad range of scientific disciplines, from basic neuroscience to cognitive psychology to computer science to social theory. It is an interdisciplinary research field that seeks to translate research findings on neural mechanisms of learning to educational practice and policy and to understand the effects of education on the brain. Neuroscience research usually focuses only on learning, but there is a developing subfield within neuroscience called “Mind, Brain and Education” (MBE) that attempts to link research with teaching. MBE researchers consider how to take advantage of the natural human attention span, how to use studies about memory systems to inform lesson planning, and how to use research on the role of emotions in learning. In neuroscience research, progress has been extraordinary, including advances in both understanding and technology. Scientists from a wide range of disciplines are being attracted to the challenge of understanding the brain. In spite of discoveries regarding the structure of the brain, we still do not understand how the nervous system allows us to see, hear, learn, remember, and plan certain actions. Educators and schools around the globe are increasingly relying on the knowledge, techniques, and programs developed based on a new understanding of how our brains work. This knowledge is being applied to the classroom. A growing amount of attention is being paid to neuroscience and how the results of empirical research may be used to help individuals learn more effectively. In this Research Topic, academic scientists, researchers, and scholars will share their experiences and research results on all aspects of brain-based learning and educational neuroscience. Furthermore, it provides a premier interdisciplinary platform for researchers, practitioners, and educators to present the latest developments, trends, and concerns. In addition, it discusses practical challenges encountered and solutions adopted in the field of Educational Neuroscience. The focus of this Research Topic is to bring together academic scientists, researchers, and scholars to exchange and share their experiences and research findings related to brain-based learning and educational neuroscience. Researchers, practitioners, and educators will also be able to present and discuss the newest innovations, trends, and concerns. This will include practical challenges encountered and solutions adopted in Educational Neuroscience as well as in related fields. All original and unpublished papers describing conceptual, constructive, empirical, experimental, or theoretical work in any area of Brain Based Learning and Educational Neuroscience or studies that explore the intersections between neuroscience, psychology, and education are highly encouraged. Aspects, topics, and critical issues of interest include, but are not limited to: neuroscience applications in enhanced-learning, how students learn mathematics and language, personal motivation, social and emotional learning, motivation, the biology of learning, brain functions and information processing, and many others.