This edited volume presents the current state of the art of genetics education and the challenges it holds for teaching as well as for learning. It addresses topics such as how genetics should be taught in order to provide students with a wide and connected view of the field. It gives in-depth aspects that should be considered for teaching genetics and the effect on the student's understanding. This book provides novel ideas for biology teachers, curriculum developers and researchers on how to confront the presented challenges in a way that may enable them to advance genetics education in the 21st century. It reviews the complexity of teaching and learning genetics, largely overlooked by biology textbooks and classroom instruction. It composes a crucial component of scientific literacy.

This book specifies the foundation for Adapted Primary Literature (APL), a novel text genre that enables the learning and teaching of science using research articles that were adapted to the knowledge level of high-school students. More than 50 years ago, J.J. Schwab suggested that Primary Scientific Articles "afford the most authentic, unretouched specimens of enquiry that we can obtain" and raised for the first time the idea that such articles can be used for "enquiry into enquiry". This book, the first to be published on this topic, presents the realization of this vision and shows how the reading and writing of scientific articles can be used for inquiry learning and teaching. It provides the origins and theory of APL and examines the concept and its importance. It outlines a detailed description of creating and using APL and provides examples for the use of the enactment of APL in classes, as well as descriptions of possible future prospects for the implementation of APL. Altogether, the book lays the foundations for the use of this authentic text genre for the learning and teaching of science in secondary schools.

This edited volume presents the current state of the art of genetics education and the challenges it holds for teaching as well as for learning. It addresses topics such as how genetics should be taught in order to provide students with a wide and connected view of the field. It gives in-depth aspects that should be considered for teaching genetics and the effect on the student's understanding. This book provides novel ideas for biology teachers, curriculum developers and researchers on how to confront the presented challenges in a way that may enable them to advance genetics education in the 21st century. It reviews the complexity of teaching and learning genetics, largely overlooked by biology textbooks and classroom instruction. It composes a crucial component of scientific literacy.

This book specifies the foundation for Adapted Primary Literature (APL), a novel text genre that enables the learning and teaching of science using research articles that were adapted to the knowledge level of high-school students. More than 50 years ago, J.J. Schwab suggested that Primary Scientific Articles “afford the most authentic, unretouched specimens of enquiry that we can obtain” and raised for the first time the idea that such articles can be used for “enquiry into enquiry”. This book, the first to be published on this topic, presents the realization of this vision and shows how the reading and writing of scientific articles can be used for inquiry learning and teaching. It provides the origins and theory of APL and examines the concept and its importance. It outlines a detailed description of creating and using APL and provides examples for the use of the enactment of APL in classes, as well as descriptions of possible future prospects for the implementation of APL. Altogether, the book lays the foundations for the use of this authentic text genre for the learning and teaching of science in secondary schools.

Over the past 50 years the Department of Science Teaching at the Weizmann Institute of Science in Israel was actively involved in all the components related to curriculum development, implementation, and research in science, mathematics, and computer science education: both learning and teaching. These initiatives are well designed and effective examples of long-term developmental and comprehensive models of reforms in the way science and mathematics are learned and taught. The 16 chapters of the book are divided into two key parts. The first part is on curriculum development in the sciences and mathematics. The second describes the implementation of these areas and its related professional development. Following these chapters, two commentaries are written by two imminent researchers in science and mathematics teaching and learning: Professor Alan Schonfeld from UC Berkeley, USA, and Professor Ilka Parchman from IPN at the University of Kiel, Germany. The book as a whole, as well as its individual chapters, are intended for a wide audience of curriculum developers, teacher educators, researchers on learning and teaching of science and mathematics and policy makers at the university level interested in advancing models of academic departments working under a common philosophy, yet under full academic freedom. Contributors are: Abraham Arcavi, Michal Armoni, Ron Blonder, Miriam Carmeli, Jason Cooper, Rachel Rosanne Eidelman, Ruhama Even, Bat-Sheva Eylon, Alex Friedlander, Nurit Hadas, Rina Hershkowitz, Avi Hofstein, Ronnie Karsenty, Boris Koichu, Dorothy Langley, Ohad Levkovich, Smadar Levy, Rachel Mamlok-Naaman, Nir Orion, Zahava Scherz, Alan Schoenfeld, Yael Shwartz, Michal Tabach, Anat Yarden and Edit Yerushalmi.

Over the past 50 years the Department of Science Teaching at the Weizmann Institute of Science in Israel was actively involved in all the components related to curriculum development, implementation, and research in science, mathematics, and computer science education: both learning and teaching. These initiatives are well designed and effective examples of long-term developmental and comprehensive models of reforms in the way science and mathematics are learned and taught. The 16 chapters of the book are divided into two key parts. The first part is on curriculum development in the sciences and mathematics. The second describes the implementation of these areas and its related professional development. Following these chapters, two commentaries are written by two imminent researchers in science and mathematics teaching and learning: Professor Alan Schonfeld from UC Berkeley, USA, and Professor Ilka Parchman from IPN at the University of Kiel, Germany. The book as a whole, as well as its individual chapters, are intended for a wide audience of curriculum developers, teacher educators, researchers on learning and teaching of science and mathematics and policy makers at the university level interested in advancing models of academic departments working under a common philosophy, yet under full academic freedom. Contributors are: Abraham Arcavi, Michal Armoni, Ron Blonder, Miriam Carmeli, Jason Cooper, Rachel Rosanne Eidelman, Ruhama Even, Bat-Sheva Eylon, Alex Friedlander, Nurit Hadas, Rina Hershkowitz, Avi Hofstein, Ronnie Karsenty, Boris Koichu, Dorothy Langley, Ohad Levkovich, Smadar Levy, Rachel Mamlok-Naaman, Nir Orion, Zahava Scherz, Alan Schoenfeld, Yael Shwartz, Michal Tabach, Anat Yarden and Edit Yerushalmi.