Science For Every Student

Every year, six million students enter college with the intention of becoming a science major by the time they graduate, only 60% of them will actually follow through. This means that close to 2.4 million students, every year, drop out of the science track. According to the New York Times, roughly 40% of students planning science majors either end up switching their major or fail to get any degree. Furthermore, aspiring pre-medical students (who comprise a large percentage of the freshmen class at most colleges, but who may not be science majors) often cite frustrations with science coursework/grading as a main motivation for changing their career plans. What Every College Science Student Should Know teaches students everything they need to know about how to succeed in school and after graduation. It s a portable guide and mentor that teaches study skills, course selection and mastery, how to do scientific research, what to expect from majors, how to find mentors, and how to apply learned skills to career development and enjoyment. Written by recent college graduates for entering college students and seniors in high school, What Every College Science Student Should Know is an invaluable resource for those who want to pursue a science degree, and it s also an inspiring narrative of remarkable students who are already changing the world through science."

"Teaching Science to Every Child provides timely and practical guidance about teaching science to all students. Particular emphasis is given to making science accessible to students who are typically pushed to the fringe - especially students of color and English language learners. Central to this text is the idea that science can be viewed as a culture, including specific methods of thinking, particular ways of communicating, and specialized kinds of tools. By using culture as a starting point and connecting it to effective instructional approaches, this text gives elementary and middle school science teachers a valuable framework to support the science learning of every student. Written in a conversational style, it treats readers as professional partners in efforts to address vital issues and implement classroom practices that will contribute to closing achievement gaps and advancing the science learning of all children. Features include "Point/Counterpoint" essays that present contrasting perspectives on a variety of science education topics; explicit connections between National Science Education Standards and chapter content; and chapter objectives, bulleted summaries, key terms; reflection and discussion questions. Additional resources are available on the updated and expanded Companion Website www.routledge.com/textbooks/9780415892582 Changes in the Second Edition Three entirely new chapters: Integrated Process Skills; Learning and Teaching; Assessment Technological tools and resources embedded throughout each chapter Increased attention to the role of theory as it relates to science teaching and learning Expanded use of science process skills for upper elementary and middle school Additional material about science notebooks "--Provided by publisher

In these pages, Kelly Morgan presents a compelling case for implementing a mastery learning science classroom and then shows us how to do it. Using research-based student performance data, Morgan compiles impressive statistics that support her assertion, OC Mastery learning results in improved student learning and motivation.OCO Showing challenges as well as benefits, this text covers a step-by-step implementation from the traditional classroom to a mastery classroom."

Science educators in the United States are adapting to a new vision of how students learn science. Children are natural explorers and their observations and intuitions about the world around them are the foundation for science learning. Unfortunately, the way science has been taught in the United States has not always taken advantage of those attributes. Some students who successfully complete their Kâ€"12 science classes have not really had the chance to "do" science for themselves in ways that harness their natural curiosity and understanding of the world around them. The introduction of the Next Generation Science Standards led many states, schools, and districts to change curricula, instruction, and professional development to align with the standards. Therefore existing assessmentsâ€"whatever their purposeâ€"cannot be used to measure the full range of activities and interactions happening in science classrooms that have adapted to these ideas because they were not designed to do so. Seeing Students Learn Science is meant to help educators improve their understanding of how students learn science and guide the adaptation of their instruction and approach to assessment. It includes examples of innovative assessment formats, ways to embed assessments in engaging classroom activities, and ideas for interpreting and using novel kinds of assessment information. It provides ideas and questions educators can use to reflect on what they can adapt right away and what they can work toward more gradually.

This readable and informative survey of key ideas about students’ thinking in science builds a bridge between theory and practice by offering clear accounts from research, and showing how they relate to actual examples of students talking about widely taught science topics. Focused on secondary students and drawing on perspectives found in the international research literature, the goal is not to offer a comprehensive account of the vast literature, but rather to provide an overview of the current state of the field suitable for those who need an understanding of core thinking about learners’ ideas in science, including science education students in teacher preparation and higher degree programs, and classroom teachers, especially those working with middle school, high school, or college level students. Such understanding can inform and enrich science teaching in ways which are more satisfying for teachers, less confusing and frustrating for learners, and so ultimately can lead to both greater scientific literacy and more positive attitudes to science.

"This timely and innovative book encourages us to ‘flip the classroom’ and empower our students to become content creators. Through creating digital media, they will not only improve their communication skills, but also gain a deeper understanding of core scientific concepts. This book will inspire science academics and science teacher educators to design learning experiences that allow students to take control of their own learning, to generate media that will stimulate them to engage with, learn about, and become effective communicators of science." Professors Susan Jones and Brian F. Yates, Australian Learning and Teaching Council Discipline Scholars for Science "Represents a giant leap forward in our understanding of how digital media can enrich not only the learning of science but also the professional learning of science teachers." Professor Tom Russell, Queen’s University, Ontario, Canada "This excellent edited collection brings together authors at the forefront of promoting media creation in science by children and young people. New media of all kinds are the most culturally significant forms in the lives of learners and the work in this book shows how they can move between home and school and provide new contexts for learning as well as an understanding of key concepts." Dr John Potter, London Knowledge Lab, Dept. of Culture, Communication and Media, University College London, UK Student-generated Digital Media in Science Education supports secondary school teachers, lecturers in universities and teacher educators in improving engagement and understanding in science by helping students unleash their enthusiasm for creating media within the science classroom. Written by pioneers who have been developing their ideas in students’ media making over the last 10 years, it provides a theoretical background, case studies, and a wide range of assignments and assessment tasks designed to address the vital issue of disengagement amongst science learners. It showcases opportunities for learners to use the tools that they already own to design, make and explain science content with five digital media forms that build upon each other— podcasts, digital stories, slowmation, video and blended media. Each chapter provides advice for implementation and evidence of engagement as learners use digital tools to learn science content, develop communication skills, and create science explanations. A student team’s music video animation of the Krebs cycle, a podcast on chemical reactions presented as commentary on a boxing match, a wiki page on an entry in the periodic table of elements, and an animation on vitamin D deficiency among hijab-wearing Muslim women are just some of the imaginative assignments demonstrated. Student-generated Digital Media in Science Education illuminates innovative ways to engage science learners with science content using contemporary digital technologies. It is a must-read text for all educators keen to effectively convey the excitement and wonder of science in the 21st century.

Most important to being a good science teacher is holding the expectation that all students can be scientists and think critically. Providing a thinking curriculum is especially important for those children in diverse classrooms who have been underserved by our educational system. OCo Becoming Scientists. Good science starts with a question, perhaps from the teacher at the start of a science unit or from the children as they wonder what makes a toy car move, how food decomposes, or why leaves change color. Using inquiry science, children discover answers to their questions in the same way that scientists doOCothey design experiments, make predictions, observe and describe, offer and test explanations, and share their conjectures with others. In essence, they construct their own understanding of how the world works through experimentation, reflection, and discussion. Look into real classrooms where teachers practice inquiry science and engage students in the science and engineering practices outlined in the Next Generation Science Standards. Rusty Bresser and Sharon Fargason show teachers how to do the following: Build on students' varied experiences, background knowledge, and readiness; Respond to the needs of students with varying levels of English language proficiency; Manage a diverse classroom during inquiry science exploration; Facilitate science discussions; Deepen their own science content knowledge. As the authors state, Inquiry science has little to do with textbooks and lectures and everything to do with our inherent need as a species to learn about and reflect on the world around us. Join your students on a journey of discovery as you explore your world via inquiry."