You may have to Search all our reviewed books and magazines, click the sign up button below to create a free account.
Robert Karplus, a professor of physics at the University of California, Berkeley, USA, became a leader in the movement to reform elementary school science in the 1960s. This book selects the enduring aspects of his work and presents them for the scientists and science educators of today. In an era when `science education for ALL students' has become the clarion call, the insights and works of Robert Karplus are as relevant now as they were in the 1960s, '70s, and '80s. This book tries to capture the essence of his life and work and presents selections of his published articles in a helpful context.
None
A basic, non-mathematical textbook for non-science students in secondary school or college. The book is based on Robert Karplus' many years of research on how beginners think about physics. In the "modeling approach" students explore and test simple analog, working and mathematical models for physical phenomena. The models provide a clear, understandable transition to the key principles and theories of physics. The book begins with the basic concepts of relative motion, reference frames, interaction, systems, and a descriptive overview of energy transfer. Subsequent chapters develop the details of temperature and heat, thermal (internal) energy, forces and work, electrical energy and electrical circuits, velocity and acceleration, Newton's Laws, motion near the surface of the earth, periodic and circular motion, celestial mechanics and gravity, pressure and kinetic theory, light and sound, waves, and modern physics (Bohr model and the basics of quantum mechanics). The "Modeling Instruction" approach is used in secondary schools throughout the US (see modeling.asu.edu). This book is especially useful in conjunction with (or as preparation for) the study of chemistry.
This book is intended to offer college faculty members the insights of the development of reasoning movement that enlighten physics educators in the late 1970s and led to a variety of college programs directed at improving the reasoning patterns used by college students. While the original materials were directed at physics concepts, they quickly expanded to include other sciences and the humanities and social sciences. On-going developments in the field will be included. The editors have introduced new topics, including discussions of Vygotsky's ideas in relation to those of Piaget, of science education research progress since 1978, of constructivist learning theory applied to educational computer games and of applications from anthropology to zoology. These materials are especially relevant for consideration by current university faculty in all subjects.
What should citizens know, value, and be able to do in preparation for life and work in the 21st century? In The Teaching of Science: 21st-Century Perspectives, renowned educator Rodger Bybee provides the perfect opportunity for science teachers, administrators, curriculum developers, and science teacher educators to reflect on this question. He encourages readers to think about why they teach science and what is important to teach.
This book is the first volume of an attempt to capture and record some of the answers to these questions—either from the pioneers themselves or from those persons who worked most closely with them. We know there are many pioneers and early trailblazers who are not included in this volume, but there are other volumes to follow. As we have posed questions, rummaged through files and oft-neglected books, and probed the memories of many individuals, we have come to realize our list of true pioneers is ever growing. There are names on the list that most of us readily recognize, and there are names of whom few of us have heard—yet who were significant in their roles as mentors or idea development and teaching. We quickly discovered that the “family tree” showing connections between these people is not a neat, clean simple branching tree, but is more like spaghetti. The connections are many, are intertwined, and all have their significance. The stories in this volume demonstrate how vital this network was in supporting the individual pioneers during their journey in difficult times and continues to be for those of us today in our own enterprise.
Although schools of law, medicine, and business are now highly respected, schools of education and the professionals they produce continue to be held in low regard. In Ed School, Geraldine Jonçich Clifford and James W. Guthrie attribute this phenomenon to issues of academic politics and gender bias as they trace the origins and development of the school of education in the United States. Drawing on case studies of leading schools of education, the authors offer a bold, controversial agenda for reform: ed schools must reorient themselves toward teachers and away from the quest for prestige in academe; they must also adhere to national professional standards, abandon the undergraduate education major, and reject the Ph.D. in education in favor of the Ed.D.
Each volume in the 7-volume series The World of Science Education reviews research in a key region of the world. These regions include North America, South and Latin America, Asia, Australia and New Zealand, Europe and Israel, North Africa and the Middle East, and Sub-Saharan Africa. The focus of this Handbook is on North American (Canada, US) science education and the scholarship that most closely supports this program. The reviews of the research situate what has been accomplished within a given field in North American rather an than international context. The purpose therefore is to articulate and exhibit regional networks and trends that produced specific forms of science education. The thrust lies in identifying the roots of research programs and sketching trajectories—focusing the changing façade of problems and solutions within regional contexts. The approach allows readers review what has been done and accomplished, what is missing, and what might be done next.
In this era of mandated high stakes and standardized testing, teachers and schools officials find themselves struggling to meet the demands for improved student achievement. At the same time, they are also expected to teach all subjects as required by national and state curriculum standards.
Ignite science learning with standards-based differentiated instruction that benefits all students. Included are methods for implementation and strategies for successfully managing the differentiated inquiry-based classroom.