Science Matters is a rare exception-a science book for the general reader that is informative enough to be a popular textbook for introductory courses in high school and college, and yet well-written enough to appeal to general readers uncomfortable with scientific jargon and complicated mathematics. And now, revised and expanded for the first time in nearly two decades, it is up-to-date, so that readers can enjoy Hazen and Trefil's refreshingly accessible explanations of the most recent developments in science, from particle physics to biotechnology.
This edited volume suggests how place-based pedagogies can respond to issues of colonialism and Indigenous sovereignty. Through dynamic new empirical and conceptual studies, international contributors examine settler colonialism, Indigenous cosmologies, Indigenous land rights, and language as key aspects of Land Education. The book invites readers to rethink 'pedagogies of place' from various Indigenous, postcolonial, and decolonizing perspectives. This book was originally published as a special issue of Environmental Education Research.
The probes are invaluable formative assesment tools to use before you begin teaching a topic or unit. The detailed teacher materials that accompany each probe review science content, give connections to National Science Education Standards and Benchmarks; present developmental considerations; summarize relevant research on learning; and suggest instructional approaches for elementary, middle, and high school students. Other books may discuss students' general misconceptions about scientific thinking about scientific ideas. Only this one provides probes, single, reproducible sheets, you can use to determine students' thinking about, for example, photosynthesis, moon phases, conservation of matter, reflections, chemical change, and cells. Each probe has been field-tested with hundreds of students across multiple grade levels, so they're proven effective for helping your students reexamine and further develop their understanding of science concepts.
As outlined in previous volumes, teachers, like their students, can have misconceptions that come to the fore when administering the probes. Volume 3 provides 10 detailed suggestions for teachers on how to use the probes to uncover, accurately assess, and correct their own preconceptions as well as their students' (e.g., do the probes yourself, examine student responses with other teachers, embed the probes into existing professional development programs, select specific areas to focus on, examine student thinking across grade spans, categorize ideas, and crunch data to create classroom profiles).
Volume 3 offers five life science probes, seven Earth and space science probes, ten physical science probes, and three nature of science probes. This volume is an invaluable resource for classroom teachers, preservice teachers, professional developers, and college science and preservice faculty.
It covers all the topics of this popular software title used in schools and colleges worldwide for over twenty years.
Now published as a portable, learning, reference and subject revision guide students, teachers and hobbyists have their own low-cost version as an eBook on their mobile phone.
Explanatory text is condensed to note form making it quick and easy to find the detail on the selected topic or to provide a content reminder for exam revision. All common formula for the subject are included using typical values with calculations and results determined from the software default inputs.
The PC software to accompany your mobile device eBook provides you with an easy and enjoyable way to study your chosen subject. Comprising hundreds of menu selected colorful topics where the graphic images on your mobile are brought to life for every value change along with many additional learning and software features.
A unique combined digital portable study device and educational software package at a tiny fraction of the previously published price.
See Additional Notes for the FREE Electronics, Mechanics, Maths and Computing V10 educational software download for your PC, to accompany this eBook title, worth a120 / $160.
What does this mean for us as individuals and for society as a whole? What are the social implications of this technological revolution that we have witnessed in the short span of about 20 years? Do people of different generations use these technologies in the same ways, or do they adopt them to support their communication habits formed at different times of their lives? How does the illusion of control provided by these technologies affect the way we think about what is meaningful in our lives? Hanson examines the wide-ranging impact of this change. How do individuals posting their viewpoints on the Internet affect democracy? Is it possible to ever completely prevent identity theft over the Internet? How permanent is information stored on the Internet or on a hard drive? Do cell phones change the way people think about privacy or the way they communicate with others? Does email? Do videogames teach new social principles? Do cell phones and the Internet change traditional communication behaviors and attitudes? Hanson discusses these crucial issues and explores to what extent individuals do have control, and she assesses how social and governmental services are responding to (or running from) the problems posed by these new technologies.
The number of African Americans and Latino/as receiving undergraduate and advanced degrees in computer science is disproportionately low, according to recent surveys. And relatively few African American and Latino/a high school students receive the kind of institutional encouragement, educational opportunities, and preparation needed for them to choose computer science as a field of study and profession. In Stuck in the Shallow End, Jane Margolis looks at the daily experiences of students and teachers in three Los Angeles public high schools: an overcrowded urban high school, a math and science magnet school, and a well-funded school in an affluent neighborhood. She finds an insidious “virtual segregation” that maintains inequality. Two of the three schools studied offer only low-level, how-to (keyboarding, cutting and pasting) introductory computing classes. The third and wealthiest school offers advanced courses, but very few students of color enroll in them. The race gap in computer science, Margolis finds, is one example of the way students of color are denied a wide range of occupational and educational futures. Margolis traces the interplay of school structures (such factors as course offerings and student-to-counselor ratios) and belief systems—including teachers' assumptions about their students and students' assumptions about themselves. Stuck in the Shallow End is a story of how inequality is reproduced in America—and how students and teachers, given the necessary tools, can change the system.
Discover why some people are far more susceptible to addiction than others as the author illuminates striking neural similarities between drugs and other pleasures potentially capable of causing abuse or addiction–including alcohol, gambling, sex, caffeine, and even Internet overuse. Kuhar concludes by outlining the 12 characteristics most often associated with successful drug addiction treatment.
Authoritative and easy to understand, The Addicted Brain offers today’s most up-to-date scientific explanation of addiction–and what addicts, their families, and society can do about it.
Successful K-12 STEM Education defines a framework for understanding "success" in K-12 STEM education. The book focuses its analysis on the science and mathematics parts of STEM and outlines criteria for identifying effective STEM schools and programs. Because a school's success should be defined by and measured relative to its goals, the book identifies three important goals that share certain elements, including learning STEM content and practices, developing positive dispositions toward STEM, and preparing students to be lifelong learners. A successful STEM program would increase the number of students who ultimately pursue advanced degrees and careers in STEM fields, enhance the STEM-capable workforce, and boost STEM literacy for all students. It is also critical to broaden the participation of women and minorities in STEM fields.
Successful K-12 STEM Education examines the vast landscape of K-12 STEM education by considering different school models, highlighting research on effective STEM education practices, and identifying some conditions that promote and limit school- and student-level success in STEM. The book also looks at where further work is needed to develop appropriate data sources. The book will serve as a guide to policy makers; decision makers at the school and district levels; local, state, and federal government agencies; curriculum developers; educators; and parent and education advocacy groups.
The amazing inside story about a gambling ring of M.I.T. students who beat the system in Vegas—and lived to tell how.
Robin Hood meets the Rat Pack when the best and the brightest of M.I.T.’s math students and engineers take up blackjack under the guidance of an eccentric mastermind. Their small blackjack club develops from an experiment in counting cards on M.I.T.’s campus into a ring of card savants with a system for playing large and winning big. In less than two years they take some of the world’s most sophisticated casinos for more than three million dollars. But their success also brings with it the formidable ire of casino owners and launches them into the seedy underworld of corporate Vegas with its private investigators and other violent heavies.
The ‘writing process’ is demystified and techniques for writing compelling, insightful and mark generating essays are conveyed via innovative and meaningful representations, templates, images, icons and prompts, specifically designed to meet the visual and ‘big picture’ strengths of dyslexic learners. A companion website offers supplementary exercises, examples, videos and a full range of downloadable templates and bookmarks.
Written by a dyslexic for dyslexics, Academic Writing and Dyslexia is underpinned by extensive research. As a dyslexic student you will learn to present your thoughts with confidence, critically evaluate competing arguments and gain top marks. The book will help you bridge the gap between your existing coping strategies and the increased demands and rigours of academic writing at university. It will be an invaluable resource for dyslexic students, academics, dyslexia specialists, learning developers and writing tutors throughout the higher education sector.
Teaching science to English Language Learners combines research findings with classroom vignettes and the perspectives of teachers. The chapter authors strive to support your efforts to see diversity as a resource, rather than as an obstacle, in the science classroom. Among their topics: building on what students know and recognizing students' strengths; teaching vocabulary for learning; supporting the development of academic language; challenges associated with learning a second language; types of programs for teaching English language learners; and using students' cultural resources.
Mastering the principles outlined in the book will give any teacher a braod base of knowledge from which to draw. But the book also urges you to think deeply about the roles of diversity. It offers valuable information for reflecting on, experimenting with, and adapting your instructional practices. As the authors note, "the vision of science teaching and learning put forward in this volume is one in which English lanaguage learners have as much to teach their fellow students as they have to learn from them."
This book begins by exploring this concept, then challenges the reader in an unconventional manner to take a stand about how they teach science. Step by step instructions are given to help the novice as well as the experienced middle and high school teacher to effectively conduct inquiry lessons. This book is linked to over six hours of video - providing teachers with model inquiry lessons in biology, chemistry, physics and earth science. Additionally, video-based evaluative guidelines are included to help teachers reflect on their instruction and improve how they conduct inquiry lessons.
Coupling a clearly articulated process of doing inquiry, with video and self-assessment, science teachers will be empowered to take their instruction to the next level, and by so doing facilitate their students' understanding of science.
(Please note that links within this book must be copied and pasted into your browser to function correctly.)
Awaken a sense of wonder in a child with the Next Time You See series from NSTA Kids. The books will inspire elementary-age children to experience the enchantment of everyday phenomena such as sunsets, seashells, fireflies, pill bugs, and more. Free supplementary activities are available on the NSTA website.
Especially designed to be experienced with an adult—be it a parent, teacher, or friend—Next Time You See books serve as a reminder that you don’t have to look far to find something remarkable in nature.
Mark Twain Media Publishing Company specializes in providing engaging supplemental books and decorative resources to complement middle- and upper-grade classrooms. Designed by leading educators, this product line covers a range of subjects including math, science, language arts, social studies, history, government, fine arts, and character.
But for their mentor, Amir Abo-Shaeer, much more hung in the balance.
The fact was, Amir had in mind a different vision for education, one based not on rote learning -- on absorbing facts and figures -- but on active creation. In his mind’s eye, he saw an even more robust academy within Dos Pueblos that would make science, technology, engineering, and math (STEM) cool again, and he knew he was poised on the edge of making that dream a reality. All he needed to get the necessary funding was one flashy win – a triumph that would firmly put his Engineering Academy at Dos Pueblos on the map. He imagined that one day there would be a nation filled with such academies, and a new popular veneration for STEM – a “new cool” – that would return America to its former innovative glory.
It was a dream shared by Dean Kamen, a modern-day inventing wizard – often-called “the Edison of his time” – who’d concocted the very same FIRST Robotics Competition that had lured the kids at Dos Pueblos. Kamen had created FIRST (For Inspiration and Recognition of Science and Technology) nearly twenty years prior. And now, with a participant alumni base approaching a million strong, he felt that awareness was about to hit critical mass.
But before the Dos Pueblos D’Penguineers could do their part in bringing a new cool to America, they’d have to vanquish an intimidating lineup of “super-teams”– high-school technology goliaths that hailed from engineering hot spots such as Silicon Valley, Massachusetts’ Route 128 technology corridor, and Michigan’s auto-design belt. Some of these teams were so good that winning wasn’t just hoped for every year, it was expected.
In The New Cool, Neal Bascomb manages to make even those who know little about – or are vaguely suspicious of – technology care passionately about a team of kids questing after a different kind of glory. In these kids’ heartaches and headaches – and yes, high-five triumphs -- we glimpse the path not just to a new way of educating our youth but of honoring the crucial skills a society needs to prosper. A new cool.
In The Science of God, distinguished physicist and Biblical scholar Gerald L. Schroeder demonstrates the surprising parallels between a variety of Biblical teachings and the findings of biochemists, paleontologists, astrophysicists, and quantum physicists. In a brilliant and wide-ranging discussion of key topics that have divided science and religion—free will, the development of the universe, the origin of life, and the origin of man—Schroeder argues that the latest science and a close reading of the Bible are not just compatible but interdependent.
This timely reissue of The Science of God features a brand-new preface by Schroeder and a compelling appendix that addresses the highly publicized experiment in 2008 in which scientists attempted to re-create the chemical composition of the cosmos immediately after the Big Bang. It also details Schroeder’s lucid explanations of complex scientific and religious concepts, such as the theory of relativity, the passage of time, and the definitions of crucial Hebrew words in the Bible. Religious skeptics, Biblical literalists, scientists, students, and physicists alike will be riveted by Schroeder’s remarkable contribution to the raging debate between science and religion.
This book is an essential resource that will guide you through setting up, creating, and maintaining interactive notebooks for skill retention in the classroom. High-interest and hands-on, interactive notebooks effectively engage students in learning new concepts. Students are encouraged to personalize interactive notebooks to fit their specific learning needs by creating fun, colorful pages for each topic. With this note-taking process, students will learn organization, color coding, summarizing, and other important skills while creating personalized portfolios of their individual learning that they can reference throughout the year.
Spanning grades kindergarten to grade 8, the Interactive Notebooks series focuses on grade-specific math, language arts, or science skills. Aligned to meet current state standards, every 96-page book in this series offers lesson plans to keep the process focused. Reproducibles are included to create notebook pages on a variety of topics, making this series a fun, one-of-a-kind learning experience.
1. How will engaging students in science and engineering practices help improve science education?
2. What do the eight practices look like in the classroom?
3. How can educators engage students in practices to bring the NGSS to life?
Helping Students Make Sense of the World Using Next Generation Science and Engineering Practices was developed for K–12 science teachers, curriculum developers, teacher educators, and administrators. Many of its authors contributed to the Framework’s initial vision and tested their ideas in actual science classrooms. If you want a fresh game plan to help students work together to generate and revise knowledge—not just receive and repeat information—this book is for you.
At the turn of the twentieth century, electricity emerged as a metaphor for modernity. Writers from Mark Twain to Ralph Ellison grappled with the idea of electricity as both life force (illumination) and death spark (electrocution). The idea that electrification created exclusively modern experiences took hold of Americans' imaginations, whether they welcomed or feared its adoption. In Power Lines, Jennifer Lieberman examines the apparently incompatible notions of electricity that coexisted in the American imagination, tracinghow electricity became a common (though multifarious) symbol for modern life.
Lieberman examines a series of moments of technical change when electricity accrued new social meanings, plotting both power lines and the power of narrative lines in American life and literature. While discussing the social construction of electrical systems,she offers a new interpretation of Twain's use of electricity as an organizing metaphor in A Connecticut Yankee in King Arthur's Court, describes the rhetoric surrounding the invention of electric execution, analyzes Charlotte Perkins Gilman's call for human connection in her utopian writing and in her little-known Human Work, considers the theme of electrical interconnection in Jack London's work, and shows how Ralph Ellison and Louis Mumford continued the literary tradition of electrical metaphor.
Electrical power was a distinctive concept in American literary, cultural, and technological histories. For this reason, narratives about electricity were particularly evocative. Bridging the realistic and the romantic, the historical and the fantastic, these stories guide us to ask new questions about our enduring fascination with electricity and all it came to represent.
From the Trade Paperback edition.
Interactive notebooks allow students to record observations, reflect on learning, and self-assess their work. Packed with student examples, this detailed guide explains the unique features that make interactive notebooks more effective tools than conventional notebooks for science classrooms. This resource:Describes the nuts and bolts of implementing interactive notebooks, including execution, time management, and grading Uses the 5E Learning Cycle as the framework for science instruction Emphasizes the importance of writing in science and provides strategies for modeling effective writing Explores strategies to encourage collaborative student inquiry and foster whole-class discussions
The book is broken into two basic parts:
1. An introduction to the stages of argument-driven inquiry--from question identification, data analysis, and argument development and evaluation to double-blind peer review and report revision.
2. A well-organized series of 27 field-tested labs that cover molecules and organisms, ecosystems, heredity, and biological evolution. The investigations are designed to be more authentic scientific experiences than traditional laboratory activities. They give your students an opportunity to design their own methods, develop models, collect and analyze data, generate arguments, and critique claims and evidence.
Because the authors are veteran teachers, they designed Argument-Driven Inquiry in Biology to be easy to use and aligned with today's standards. The labs include reproducible student pages and teacher notes. The investigations will help your students learn the core ideas, crosscutting concepts, and scientific practices found in the Next Generation Science Standards. In addition, they offer ways for students to develop the disciplinary skills outlined in the Common Core State Standards.
Many of today's teachers--like you--want to find new ways to engage students in scientific practices and help students learn more from lab activities. Argument-Driven Inquiry in Biology does all of this even as it gives students the chance to practice reading, writing, speaking, and using math in the context of science.
Like the original edition, this book offers exciting new research about the mind and the brain that provides answers to a number of compelling questions. When do infants begin to learn? How do experts learn and how is this different from non-experts? What can teachers and schools do-with curricula, classroom settings, and teaching methods--to help children learn most effectively? New evidence from many branches of science has significantly added to our understanding of what it means to know, from the neural processes that occur during learning to the influence of culture on what people see and absorb.
How People Learn examines these findings and their implications for what we teach, how we teach it, and how we assess what our children learn. The book uses exemplary teaching to illustrate how approaches based on what we now know result in in-depth learning. This new knowledge calls into question concepts and practices firmly entrenched in our current education system.
Topics include: How learning actually changes the physical structure of the brain. How existing knowledge affects what people notice and how they learn. What the thought processes of experts tell us about how to teach. The amazing learning potential of infants. The relationship of classroom learning and everyday settings of community and workplace. Learning needs and opportunities for teachers. A realistic look at the role of technology in education.
A Framework for K-12 Science Education outlines a broad set of expectations for students in science and engineering in grades K-12. These expectations will inform the development of new standards for K-12 science education and, subsequently, revisions to curriculum, instruction, assessment, and professional development for educators. This book identifies three dimensions that convey the core ideas and practices around which science and engineering education in these grades should be built. These three dimensions are: crosscutting concepts that unify the study of science through their common application across science and engineering; scientific and engineering practices; and disciplinary core ideas in the physical sciences, life sciences, and earth and space sciences and for engineering, technology, and the applications of science. The overarching goal is for all high school graduates to have sufficient knowledge of science and engineering to engage in public discussions on science-related issues, be careful consumers of scientific and technical information, and enter the careers of their choice.
A Framework for K-12 Science Education is the first step in a process that can inform state-level decisions and achieve a research-grounded basis for improving science instruction and learning across the country. The book will guide standards developers, teachers, curriculum designers, assessment developers, state and district science administrators, and educators who teach science in informal environments.
High School Mathematics at Work illuminates the interplay between technical and academic mathematics. This collection of thought-provoking essays--by mathematicians, educators, and other experts--is enhanced with illustrative tasks from workplace and everyday contexts that suggest ways to strengthen high school mathematical education.
This important book addresses how to make mathematical education of all students meaningful--how to meet the practical needs of students entering the work force after high school as well as the needs of students going on to postsecondary education.
The short readable essays frame basic issues, provide background, and suggest alternatives to the traditional separation between technical and academic mathematics. They are accompanied by intriguing multipart problems that illustrate how deep mathematics functions in everyday settings--from analysis of ambulance response times to energy utilization, from buying a used car to "rounding off" to simplify problems.
The book addresses the role of standards in mathematics education, discussing issues such as finding common ground between science and mathematics education standards, improving the articulation from school to work, and comparing SAT results across settings.
Experts discuss how to develop curricula so that students learn to solve problems they are likely to encounter in life--while also providing them with approaches to unfamiliar problems. The book also addresses how teachers can help prepare students for postsecondary education.
For teacher education the book explores the changing nature of pedagogy and new approaches to teacher development. What kind of teaching will allow mathematics to be a guide rather than a gatekeeper to many career paths? Essays discuss pedagogical implication in problem-centered teaching, the role of complex mathematical tasks in teacher education, and the idea of making open-ended tasks--and the student work they elicit--central to professional discourse.
High School Mathematics at Work presents thoughtful views from experts. It identifies rich possibilities for teaching mathematics and preparing students for the technological challenges of the future. This book will inform and inspire teachers, teacher educators, curriculum developers, and others involved in improving mathematics education and the capabilities of tomorrow's work force.