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| example of science literacy: Science Literacy National Academies of Sciences, Engineering, and Medicine, Division of Behavioral and Social Sciences and Education, Board on Science Education, Committee on Science Literacy and Public Perception of Science, 2016-11-14 Science is a way of knowing about the world. At once a process, a product, and an institution, science enables people to both engage in the construction of new knowledge as well as use information to achieve desired ends. Access to scienceâ€whether using knowledge or creating itâ€necessitates some level of familiarity with the enterprise and practice of science: we refer to this as science literacy. Science literacy is desirable not only for individuals, but also for the health and well- being of communities and society. More than just basic knowledge of science facts, contemporary definitions of science literacy have expanded to include understandings of scientific processes and practices, familiarity with how science and scientists work, a capacity to weigh and evaluate the products of science, and an ability to engage in civic decisions about the value of science. Although science literacy has traditionally been seen as the responsibility of individuals, individuals are nested within communities that are nested within societiesâ€and, as a result, individual science literacy is limited or enhanced by the circumstances of that nesting. Science Literacy studies the role of science literacy in public support of science. This report synthesizes the available research literature on science literacy, makes recommendations on the need to improve the understanding of science and scientific research in the United States, and considers the relationship between scientific literacy and support for and use of science and research. |
| example of science literacy: The Myth of Scientific Literacy Morris Herbert Shamos, 1995 Shamos argues that a meaningful scientific literacy cannot be achieved in the first place, and the attempt is a misuse of human resources on a grand scale. He is skeptical about forecasts of critical shortfalls in scientific manpower and about the motives behind crash programs to get more young people into the science pipeline. |
| example of science literacy: Systems for State Science Assessment National Research Council, Division of Behavioral and Social Sciences and Education, Center for Education, Board on Testing and Assessment, Committee on Test Design for K-12 Science Achievement, 2005-12-28 In response to the No Child Left Behind Act of 2001 (NCLB), Systems for State Science Assessment explores the ideas and tools that are needed to assess science learning at the state level. This book provides a detailed examination of K-12 science assessment: looking specifically at what should be measured and how to measure it. Along with reading and mathematics, the testing of science is a key component of NCLBâ€it is part of the national effort to establish challenging academic content standards and develop the tools to measure student progress toward higher achievement. The book will be a critical resource for states that are designing and implementing science assessments to meet the 2007-2008 requirements of NCLB. In addition to offering important information for states, Systems for State Science Assessment provides policy makers, local schools, teachers, scientists, and parents with a broad view of the role of testing and assessment in science education. |
| example of science literacy: Benchmarks for Science Literacy American Association for the Advancement of Science, 1994-01-06 Published to glowing praise in 1990, Science for All Americans defined the science-literate American--describing the knowledge, skills, and attitudes all students should retain from their learning experience--and offered a series of recommendations for reforming our system of education in science, mathematics, and technology. Benchmarks for Science Literacy takes this one step further. Created in close consultation with a cross-section of American teachers, administrators, and scientists, Benchmarks elaborates on the recommendations to provide guidelines for what all students should know and be able to do in science, mathematics, and technology by the end of grades 2, 5, 8, and 12. These grade levels offer reasonable checkpoints for student progress toward science literacy, but do not suggest a rigid formula for teaching. Benchmarks is not a proposed curriculum, nor is it a plan for one: it is a tool educators can use as they design curricula that fit their student's needs and meet the goals first outlined in Science for All Americans. Far from pressing for a single educational program, Project 2061 advocates a reform strategy that will lead to more curriculum diversity than is common today. IBenchmarks emerged from the work of six diverse school-district teams who were asked to rethink the K-12 curriculum and outline alternative ways of achieving science literacy for all students. These teams based their work on published research and the continuing advice of prominent educators, as well as their own teaching experience. Focusing on the understanding and interconnection of key concepts rather than rote memorization of terms and isolated facts, Benchmarks advocates building a lasting understanding of science and related fields. In a culture increasingly pervaded by science, mathematics, and technology, science literacy require habits of mind that will enable citizens to understand the world around them, make some sense of new technologies as they emerge and grow, and deal sensibly with problems that involve evidence, numbers, patterns, logical arguments, and technology--as well as the relationship of these disciplines to the arts, humanities, and vocational sciences--making science literacy relevant to all students, regardless of their career paths. If Americans are to participate in a world shaped by modern science and mathematics, a world where technological know-how will offer the keys to economic and political stability in the twenty-first century, education in these areas must become one of the nation's highest priorities. Together with Science for All Americans, Benchmarks for Science Literacy offers a bold new agenda for the future of science education in this country, one that is certain to prepare our children for life in the twenty-first century. |
| example of science literacy: Science Communication Annette Leßmöllmann, Marcelo Dascal, Thomas Gloning, 2019-12-16 The volume gives a multi-perspective overview of scholarly and science communication, exploring its diverse functions, modalities, interactional structures, and dynamics in a rapidly changing world. In addition, it provides a guide to current research approaches and traditions on communication in many disciplines, including the humanities, technology, social and natural sciences, and on forms of communication with a wide range of audiences. |
| example of science literacy: Reading and Writing in Science Maria C. Grant, Douglas Fisher, Diane Lapp, 2015-01-21 Engage your students in scientific thinking across disciplines! Did you know that scientists spend more than half of their time reading and writing? Students who are science literate can analyze, present, and defend data – both orally and in writing. The updated edition of this bestseller offers strategies to link the new science standards with literacy expectations, and specific ideas you can put to work right away. Features include: A discussion of how to use science to develop essential 21st century skills Instructional routines that help students become better writers Useful strategies for using complex scientific texts in the classroom Tools to monitor student progress through formative assessment Tips for high-stakes test preparation |
| example of science literacy: Science Literacy in Primary Schools and Pre-Schools Haim Eshach, 2006-08-12 This well-written and thought-provoking book presents the state-of-the-art in science education for kindergarten and primary schools. It begins with a thorough theoretical discussion on why it is incumbent on the science educator to teach science at first stages of childhood. It goes on to analyze and synthesize a broad range of educational approaches and themes. The book also presents novel strategies to science teaching. |
| example of science literacy: Science Matters Robert M. Hazen, James Trefil, 2009-06-09 A science book for the general reader that is informative enough to be a popular textbook and yet well-written enough to appeal to general readers. “Hazen and Trefil [are] unpretentious—good, down-to-earth, we-can-explain-anything science teachers, the kind you wish you had but never did.”—The New York Times Book Review Knowledge of the basic ideas and principles of science is fundamental to cultural literacy. But most books on science are often too obscure or too specialized to do the general reader much good. Science Matters is a rare exception—a science book that is informative enough for introductory courses in high school and college, and yet lucid enough for readers uncomfortable with scientific jargon and complicated mathematics. And now, revised and expanded, 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. |
| example of science literacy: Atlas of Science Literacy , 2001 An oversized book with ambitious goals: That's the Atlas of Science Literacy. Asking -- then answering -- such vital questions as: -- What should students learn? -- When should they learn it -- and in what order? -- How does each strand of knowledge connect to other vital threads? This new educational tool from AAAS's Project 2061 graphically depicts connections among the learning goals established in Benchmarks for Science Literacy and Science for All Americans. The Atlas is a collection of 50 linked maps that show exactly how students from kindergarten through 12th grade can expand their understanding and skills toward specific science-literacy goals. But the maps don't just show the sequence of Benchmark ideas that lead to a goal. They also show the connections across different areas of mathematics, technology, and (of course) science -- including gravity, evolution and natural selection, the structure of matter, and the flow of matter and energy in ecosystems. This groundbreaking book is every school's road map to helping children learn science systematically. Using the Atlas of Science Literacy as your guide, trace the prerequisites for learning in each grade, make the connections to support science content, and show the way to the next steps to learning for your students. |
| example of science literacy: Reading Science Jennifer L. Altieri, 2016 How can we prepare our students to think, read, and write like scientists? In Reading Science, Jennifer Altieri reminds us that literacy skills aren't add-ons to the science class-they are critical parts of instruction. She addresses the need for both literacy and science skills in our classrooms to prepare our students for the future challenges they will meet. Strategies you can use right away Filled with practical strategies customized for science classrooms based on Jennifer's decades of experience connecting content areas with literacy, this book supports: teaching students to be critical consumers of scientific information they read, regardless of the source or type of text developing students' interest in scientific vocabulary and rich understanding of how words relate to each other encouraging collaboration as students seek answers to scientific questions and communicate their findings. Science requires specialized literacy demands Our students should be prepared for not only the science class as we know it today but for future science classes and the world beyond. To create classrooms that support this kind of learning, we must use literacy as a tool to help students access science content, communicate their ideas precisely, and apply their discoveries in new contexts. |
| example of science literacy: The Science of Reading Margaret J. Snowling, Charles Hulme, 2008-04-15 The Science of Reading: A Handbook brings together state-of-the-art reviews of reading research from leading names in the field, to create a highly authoritative, multidisciplinary overview of contemporary knowledge about reading and related skills. Provides comprehensive coverage of the subject, including theoretical approaches, reading processes, stage models of reading, cross-linguistic studies of reading, reading difficulties, the biology of reading, and reading instruction Divided into seven sections:Word Recognition Processes in Reading; Learning to Read and Spell; Reading Comprehension; Reading in Different Languages; Disorders of Reading and Spelling; Biological Bases of Reading; Teaching Reading Edited by well-respected senior figures in the field |
| example of science literacy: Scientific Literacy and the Myth of the Scientific Method Henry H. Bauer, 1992 What is science? Is social science a science? Why are more and more so-called scientific discoveries being exposed as outright frauds? Henry Bauer tackles these and many more intriguing questions that are emerging from within the academic and scientific communities and attracting attention from the popular media and the general public. Whether one is a specialist or generalist, scientist or humanist, thinker or activist, it is important to understand the place of science and technology in modern life. Popular views about the nature of science and scientific activity contain serious misconceptions that were discarded decades ago by most historians and philosophers of science. The perpetuation of these misconceptions usually surface in the form of frustrating and unproductive discussions about everything from setting policy and defining technical matters to whether one individual's point of view is ''right'' because it is supported by ''scientific facts.'' According to Bauer, the most serious and widespread misconceptions are that ''science'' can be discussed as though all sciences share a great deal in common and as though ''the scientific method'' characterizes all sciences. ''Science,'' argues Bauer, ''can be understood only if one recognizes it as a quest by fallible human beings who have evolved ways of interacting that help them gain relatively objective knowledge.'' In other words, science is a social activity, not simply the result of impersonal methods. Concern has recently arisen over the quality of American education and our declining scientific and research orientation. Debates are emerging about what direction public universities should be taking as we head into the twenty-fist century. Why and to what extent should society support basic scientific research? What should everyone in a democratic society know about science? This book will help readers come to an informed understanding about the place of science and technology in today's world.''Provocative. . . . Bauer argues that science does not proceed by the scientific method. If it did, experiments would inspire hypotheses which would then be tested until they generated reliable theories. As Watson and Crick's work [on DNA] shows, an elegant idea is often a headier lure than mere facts.''--Newsweek ''Sound, sensible . . . and very easy to read. . . . I would strongly recommend this book to anyone who hasn't yet heard that the scientific method is a myth.''--Science ''This is a book that every science teacher should read and consider. It will certainly affect their views of what science really is and influence their teaching.''--The Science Teacher |
| example of science literacy: Language and Literacy in Science Education Jerry Wellington, Jonathan Osborne, 2001-03-16 Science in secondary schools has tended to be viewed mainly as a 'practical subject', and language and literacy in science education have been neglected. But learning the language of science is a major part of science education: every science lesson is a language lesson, and language is a major barrier to most school students in learning science. This accessible book explores the main difficulties in the language of science and examines practical ways to aid students in retaining, understanding, reading, speaking and writing scientific language. Jerry Wellington and Jonathan Osborne draw together and synthesize current good practice, thinking and research in this field. They use many practical examples, illustrations and tried-and-tested materials to exemplify principles and to provide guidelines in developing language and literacy in the learning of science. They also consider the impact that the growing use of information and communications technology has had, and will have, on writing, reading and information handling in science lessons. The authors argue that paying more attention to language in science classrooms is one of the most important acts in improving the quality of science education. This is a significant and very readable book for all student and practising secondary school science teachers, for science advisers and school mentors. |
| example of science literacy: PISA 2018 Assessment and Analytical Framework OECD, 2019-04-26 This report presents the conceptual foundations of the OECD Programme for International Student Assessment (PISA), now in its seventh cycle of comprehensive and rigorous international surveys of student knowledge, skills and well-being. Like previous cycles, the 2018 assessment covered reading, mathematics and science, with the major focus this cycle on reading literacy, plus an evaluation of students’ global competence – their ability to understand and appreciate the perspectives and world views of others. Financial literacy was also offered as an optional assessment. |
| example of science literacy: Cognition, Metacognition, and Culture in STEM Education Yehudit Judy Dori, Zemira R. Mevarech, Dale R. Baker, 2017-12-01 This book addresses the point of intersection between cognition, metacognition, and culture in learning and teaching Science, Technology, Engineering, and Mathematics (STEM). We explore theoretical background and cutting-edge research about how various forms of cognitive and metacognitive instruction may enhance learning and thinking in STEM classrooms from K-12 to university and in different cultures and countries. Over the past several years, STEM education research has witnessed rapid growth, attracting considerable interest among scholars and educators. The book provides an updated collection of studies about cognition, metacognition and culture in the four STEM domains. The field of research, cognition and metacognition in STEM education still suffers from ambiguity in meanings of key concepts that various researchers use. This book is organized according to a unique manner: Each chapter features one of the four STEM domains and one of the three themes—cognition, metacognition, and culture—and defines key concepts. This matrix-type organization opens a new path to knowledge in STEM education and facilitates its understanding. The discussion at the end of the book integrates these definitions for analyzing and mapping the STEM education research. Chapter 4 is available open access under a Creative Commons Attribution 4.0 International License via link.springer.com |
| example of science literacy: What Successful Science Teachers Do Neal A. Glasgow, Michele Cheyne, Randy K. Yerrick, 2010-09-20 This easy-to-use guide features 75 research-based strategies for teachers of students in Grades K–12. Engage your students' creativity and build their science literacy. |
| example of science literacy: Unscientific America Chris Mooney, Sheril Kirshenbaum, 2009-07-14 In his famous 1959 Rede lecture at Cambridge University, the scientifically-trained novelist C.P. Snow described science and the humanities as two cultures, separated by a gulf of mutual incomprehension. And the humanists had all the cultural power -- the low prestige of science, Snow argued, left Western leaders too little educated in scientific subjects that were increasingly central to world problems: the elementary physics behind nuclear weapons, for instance, or the basics of plant science needed to feed the world's growing population. Now, Chris Mooney and Sheril Kirshenbaum, a journalist-scientist team, offer an updated two cultures polemic for America in the 21st century. Just as in Snow's time, some of our gravest challenges -- climate change, the energy crisis, national economic competitiveness -- and gravest threats -- global pandemics, nuclear proliferation -- have fundamentally scientific underpinnings. Yet we still live in a culture that rarely takes science seriously or has it on the radar. For every five hours of cable news, less than a minute is devoted to science; 46 percent of Americans reject evolution and think the Earth is less than 10,000 years old; the number of newspapers with weekly science sections has shrunken by two-thirds over the past several decades. The public is polarized over climate change -- an issue where political party affiliation determines one's view of reality -- and in dangerous retreat from childhood vaccinations. Meanwhile, only 18 percent of Americans have even met a scientist to begin with; more than half can't name a living scientist role model. For this dismaying situation, Mooney and Kirshenbaum don't let anyone off the hook. They highlight the anti-intellectual tendencies of the American public (and particularly the politicians and journalists who are supposed to serve it), but also challenge the scientists themselves, who despite the best of intentions have often failed to communicate about their work effectively to a broad public -- and so have ceded their critical place in the public sphere to religious and commercial propagandists. A plea for enhanced scientific literacy, Unscientific America urges those who care about the place of science in our society to take unprecedented action. We must begin to train a small army of ambassadors who can translate science's message and make it relevant to the media, to politicians, and to the public in the broadest sense. An impassioned call to arms worthy of Snow's original manifesto, this book lays the groundwork for reintegrating science into the public discourse -- before it's too late. |
| example of science literacy: Science Education as a Pathway to Teaching Language Literacy , 2010-01-01 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. |
| example of science literacy: Science Denial Gale M. Sinatra, Barbara K. Hofer, 2021-06-22 How do individuals decide whether to accept human causes of climate change, vaccinate their children against childhood diseases, or practice social distancing during a pandemic? Democracies depend on educated citizens who can make informed decisions for the benefit of their health and well-being, as well as their communities, nations, and planet. Understanding key psychological explanations for science denial and doubt can help provide a means for improving scientific literacy and understandingcritically important at a time when denial has become deadly. In Science Denial: Why It Happens and What to Do About It, the authors identify the problem and why it matters and offer tools for addressing it. This book explains both the importance of science education and its limitations, shows how science communicators may inadvertently contribute to the problem, and explains how the internet and social media foster misinformation and disinformation. The authors focus on key psychological constructs such as reasoning biases, social identity, epistemic cognition, and emotions and attitudes that limit or facilitate public understanding of science, and describe solutions for individuals, educators, science communicators, and policy makers. If you have ever wondered why science denial exists, want to know how to understand your own biases and those of others, and would like to address the problem, this book will provide the insights you are seeking. |
| example of science literacy: Science and the Educated American Jerrold Meinwald, John G. Hildebrand, 2010 |
| example of science literacy: Rethinking Scientific Literacy Wolff-Michael Roth, Angela Calabrese Barton, 2004 First Published in 2004. Routledge is an imprint of Taylor & Francis, an informa company. |
| example of science literacy: Engaging with Contemporary Challenges through Science Education Research Olivia Levrini, Giulia Tasquier, Tamer G. Amin, Laura Branchetti, Mariana Levin, 2021-09-24 This book starts with the premise that beauty can be an engine of transformation and authentic engagement in an increasingly complex world. It presents an organized picture of highlights from the 13th European Science Education Research Association Conference, ESERA 2019, held in Bologna, Italy. The collection includes contributions that discuss contemporary issues such as climate change, multiculturalism, and the flourishing of new interdisciplinary areas of investigation, including the application of cognitive neuroscience, artificial intelligence, and digital humanities to science education research. It also highlights learners’ difficulties engaging with socio-scientific issues in a digital and post-truth era. The volume demonstrates that deepening our understanding is the preferred way to address these challenges and that science education has a key role to play in this effort. In particular, the book advances the argument that the deep and novel character of these challenges requires a collective search for new narratives and languages, an expanding knowledge base and new theoretical perspectives and methods of research. The book provides a contemporary picture of science education research and looks to the theoretical and practical societal challenges of the future. |
| example of science literacy: Literacy for Science National Research Council, Board on Science Education, Division of Behavioral and Social Sciences and Education, 2014 Because the CCSS literacy in science standards predated the NGSS, developers of the NGSS worked directly with the CCSS team to identify the connections between the two sets of standards. However, questions about how the two sets of standards can complement each other and can be used in concert to improve students' reading and writing, as well as listening and speaking, in science to learn science continue to exist. Literacy for Science is the summary of a workshop convened by the National Research Council Board on Science Education in December 2013 to address the need to coordinate the literacy for science aspect of CCSS and the practices in NGSS. The workshop featured presentations about the complementary roles of English/language arts teachers and science teachers as well as the unique challenges and approaches for different grade levels. |
| example of science literacy: Developing Science Literacy in the 21st Century Keri-Anne Croce, Jonah Firestone, 2020-02-01 The development of science literacy has the potential to have an enormous impact on real world outcomes. Specifically, developing science literacy may persuade individuals to act. We hope that this book will influence scientists, science journalists, sociologists, anthropologists, communication specialists, political leaders, media outlets, educational institutions, and individual science content consumers. The chapters in this book describe a definition of science literacy that draws on the emotional, cognitive, and social. The authors strive to help prepare individuals to read, write, and speak science in a continuously evolving information landscape. In order to meet these objectives, the chapters examine both qualitative and quantitative research. It is within these frameworks that we can begin to address science literacy in the 21st century. |
| example of science literacy: Uncovering the Logic of English: A Common-Sense Solution to America's Literacy Crisis Denise Eide, 2011-01-27 English is so illogical! It is generally believed that English is a language of exceptions. For many, learning to spell and read is frustrating. For some, it is impossible... especially for the 29% of Americans who are functionally illiterate. But what if the problem is not the language itself, but the rules we were taught? What if we could see the complexity of English as a powerful tool rather than a hindrance? --Denise Eide Uncovering the Logic of English challenges the notion that English is illogical by systematically explaining English spelling and answering questions like Why is there a silent final E in have, large, and house? and Why is discussion spelled with -sion rather than -tion? With easy-to-read examples and anecdotes, this book describes: - the phonograms and spelling rules which explain 98% of English words - how English words are formed and how this knowledge can revolutionize vocabulary development - how understanding the reasons behind English spelling prevents students from needing to guess The author's inspiring commentary makes a compelling case that understanding the logic of English could transform literacy education and help solve America's literacy crisis. Thorough and filled with the latest linguistic and reading research, Uncovering the Logic of English demonstrates why this systematic approach should be as foundational to our education as 1+1=2. |
| example of science literacy: Education for Life and Work National Research Council, Division of Behavioral and Social Sciences and Education, Board on Science Education, Board on Testing and Assessment, Committee on Defining Deeper Learning and 21st Century Skills, 2013-01-18 Americans have long recognized that investments in public education contribute to the common good, enhancing national prosperity and supporting stable families, neighborhoods, and communities. Education is even more critical today, in the face of economic, environmental, and social challenges. Today's children can meet future challenges if their schooling and informal learning activities prepare them for adult roles as citizens, employees, managers, parents, volunteers, and entrepreneurs. To achieve their full potential as adults, young people need to develop a range of skills and knowledge that facilitate mastery and application of English, mathematics, and other school subjects. At the same time, business and political leaders are increasingly asking schools to develop skills such as problem solving, critical thinking, communication, collaboration, and self-management - often referred to as 21st century skills. Education for Life and Work: Developing Transferable Knowledge and Skills in the 21st Century describes this important set of key skills that increase deeper learning, college and career readiness, student-centered learning, and higher order thinking. These labels include both cognitive and non-cognitive skills- such as critical thinking, problem solving, collaboration, effective communication, motivation, persistence, and learning to learn. 21st century skills also include creativity, innovation, and ethics that are important to later success and may be developed in formal or informal learning environments. This report also describes how these skills relate to each other and to more traditional academic skills and content in the key disciplines of reading, mathematics, and science. Education for Life and Work: Developing Transferable Knowledge and Skills in the 21st Century summarizes the findings of the research that investigates the importance of such skills to success in education, work, and other areas of adult responsibility and that demonstrates the importance of developing these skills in K-16 education. In this report, features related to learning these skills are identified, which include teacher professional development, curriculum, assessment, after-school and out-of-school programs, and informal learning centers such as exhibits and museums. |
| example of science literacy: Secrets to Success for Science Teachers Ellen Kottler, Victoria Brookhart Costa, 2015-10-27 This easy-to-read guide provides new and seasoned teachers with practical ideas, strategies, and insights to help address essential topics in effective science teaching, including emphasizing inquiry, building literacy, implementing technology, using a wide variety of science resources, and maintaining student safety. |
| example of science literacy: Science for All Americans F. James Rutherford, Andrew Ahlgren, 1991-02-14 In order to compete in the modern world, any society today must rank education in science, mathematics, and technology as one of its highest priorities. It's a sad but true fact, however, that most Americans are not scientifically literate. International studies of educational performance reveal that U.S. students consistently rank near the bottom in science and mathematics. The latest study of the National Assessment of Educational Progress has found that despite some small gains recently, the average performance of seventeen-year-olds in 1986 remained substantially lower than it had been in 1969. As the world approaches the twenty-first century, American schools-- when it comes to the advancement of scientific knowledge-- seem to be stuck in the Victorian age. In Science for All Americans, F. James Rutherford and Andrew Ahlgren brilliantly tackle this devastating problem. Based on Project 2061, a scientific literacy initiative sponsored by the American Association for the Advancement of Science, this wide-ranging, important volume explores what constitutes scientific literacy in a modern society; the knowledge, skills, and attitudes all students should acquire from their total school experience from kindergarten through high school; and what steps this country must take to begin reforming its system of education in science, mathematics, and technology. Science for All Americans describes the scientifically literate person as one who knows that science, mathematics, and technology are interdependent enterprises with strengths and limitations; who understands key concepts and principles of science; who recognizes both the diversity and unity of the natural world; and who uses scientific knowledge and scientific ways of thinking for personal and social purposes. Its recommendations for educational reform downplay traditional subject categories and instead highlight the connections between them. It also emphasizes ideas and thinking skills over the memorization of specialized vocabulary. For instance, basic scientific literacy means knowing that the chief function of living cells is assembling protein molecules according to the instructions coded in DNA molecules, but does not mean necessarily knowing the terms ribosome or deoxyribonucleic acid. Science, mathematics, and technology will be at the center of the radical changes in the nature of human existence that will occur during the next life span; therefore, preparing today's children for tomorrow's world must entail a solid education in these areas. Science for All Americans will help pave the way for the necessary reforms in America's schools. |
| example of science literacy: Learning and Performance Assessment: Concepts, Methodologies, Tools, and Applications Management Association, Information Resources, 2019-10-11 As teaching strategies continue to change and evolve, and technology use in classrooms continues to increase, it is imperative that their impact on student learning is monitored and assessed. New practices are being developed to enhance students’ participation, especially in their own assessment, be it through peer-review, reflective assessment, the introduction of new technologies, or other novel solutions. Educators must remain up-to-date on the latest methods of evaluation and performance measurement techniques to ensure that their students excel. Learning and Performance Assessment: Concepts, Methodologies, Tools, and Applications is a vital reference source that examines emerging perspectives on the theoretical and practical aspects of learning and performance-based assessment techniques and applications within educational settings. Highlighting a range of topics such as learning outcomes, assessment design, and peer assessment, this multi-volume book is ideally designed for educators, administrative officials, principals, deans, instructional designers, school boards, academicians, researchers, and education students seeking coverage on an educator’s role in evaluation design and analyses of evaluation methods and outcomes. |
| example of science literacy: The Love Hypothesis Ali Hazelwood, 2021-09-14 The Instant New York Times Bestseller and TikTok Sensation! As seen on THE VIEW! A BuzzFeed Best Summer Read of 2021 When a fake relationship between scientists meets the irresistible force of attraction, it throws one woman's carefully calculated theories on love into chaos. As a third-year Ph.D. candidate, Olive Smith doesn't believe in lasting romantic relationships--but her best friend does, and that's what got her into this situation. Convincing Anh that Olive is dating and well on her way to a happily ever after was always going to take more than hand-wavy Jedi mind tricks: Scientists require proof. So, like any self-respecting biologist, Olive panics and kisses the first man she sees. That man is none other than Adam Carlsen, a young hotshot professor--and well-known ass. Which is why Olive is positively floored when Stanford's reigning lab tyrant agrees to keep her charade a secret and be her fake boyfriend. But when a big science conference goes haywire, putting Olive's career on the Bunsen burner, Adam surprises her again with his unyielding support and even more unyielding...six-pack abs. Suddenly their little experiment feels dangerously close to combustion. And Olive discovers that the only thing more complicated than a hypothesis on love is putting her own heart under the microscope. |
| example of science literacy: PISA Assessing Scientific, Reading and Mathematical Literacy A Framework for PISA 2006 OECD, 2006-09-11 Presents the conceptual framework underlying the PISA 2006 survey. |
| example of science literacy: Achieving Scientific Literacy Rodger W. Bybee, 1997 Achieving Scientific Literacy offers a broad vision for improving science education. |
| example of science literacy: PISA Science 2006 Rodger W. Bybee, Barry McCrae, 2009 What must we teach students to enable them to fully participate in a world community where science and technology play an increasingly significant role? Comprehensive, thought-provoking, and indispensable, PISA Science 2006, provides educators with a top-down view of where we stand today in science education and what this means for students and educators. |
| example of science literacy: Buzzing with Questions Janice N. Harrington, 2020-06-16 The story of Charles Henry Turner, the first Black entomologist — a scientist who studies bugs — is told in this fascinating book for young readers. Can spiders learn? How do ants find their way home? Can bugs see color? All of these questions buzzed endlessly in Charles Henry Turner’s mind. He was fascinated by plants and animals and bugs. And even when he faced racial prejudice, Turner did not stop wondering. He constantly read, researched, and experimented. Author Janice Harrington and artist Theodore Taylor III capture the life of this inspiring scientist and educator in this nonfiction picture book, highlighting Turner's unstoppable quest for knowledge and his passion for science. The extensive back matter includes an author's note, time line, bibliography, source notes, and archival images. |
| example of science literacy: Rigorous Reading Nancy Frey, Douglas Fisher, 2013-08-30 What it really means to “read closely” Call it close reading, call it deep reading, call it analytic reading—call it what you like. The point is, it’s a level of understanding that students of any age can achieve with the right kind of instruction. In Rigorous Reading, Nancy Frey and Doug Fisher articulate an instructional plan so clearly, and so squarely built on research, that teachers, schools, and districts need look no further: Purpose & Modeling Close & Scaffolded Reading Instruction Collaborative Conversations An Independent Reading Staircase Performance |
| example of science literacy: PISA The PISA 2003 Assessment Framework Mathematics, Reading, Science and Problem Solving Knowledge and Skills OECD, 2004-03-02 The PISA 2003 Assessment Framework presents the conceptual underpinning of the PISA 2003 assessments. Within each assessment area, the volume defines the content that students need to acquire, the processes that need to be performed and the contexts in which knowledge and skills are applied. |
| example of science literacy: Intersections of Formal and Informal Science Lucy Avraamidou, Wolff-Michael Roth, 2016-03-10 Science learning that takes place between and at the intersections of formal and informal science environments has not been systematically reviewed to offer a comprehensive understanding of the existing knowledge base. Bringing together theory and research, this volume describes the various ways in which learning science in various settings has been conceptualized as well as empirical evidence to illustrate how science learning in these settings can be supported. |
| example of science literacy: Picture-Perfect Science Lessons Karen Rohrich Ansberry, Emily Rachel Morgan, 2010 In this newly revised and expanded 2nd edition of Picture-Perfect Science Lessons, classroom veterans Karen Ansberry and Emily Morgan, who also coach teachers through nationwide workshops, offer time-crunched elementary educators comprehensive background notes to each chapter, new reading strategies, and show how to combine science and reading in a natural way with classroom-tested lessons in physical science, life science, and Earth and space science. |
| example of science literacy: A Framework for K-12 Science Education National Research Council, Division of Behavioral and Social Sciences and Education, Board on Science Education, Committee on a Conceptual Framework for New K-12 Science Education Standards, 2012-02-28 Science, engineering, and technology permeate nearly every facet of modern life and hold the key to solving many of humanity's most pressing current and future challenges. The United States' position in the global economy is declining, in part because U.S. workers lack fundamental knowledge in these fields. To address the critical issues of U.S. competitiveness and to better prepare the workforce, A Framework for K-12 Science Education proposes a new approach to K-12 science education that will capture students' interest and provide them with the necessary foundational knowledge in the field. 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. |
| example of science literacy: The Roadmap to Literacy Renewal of Literacy Edition Jennifer Irene Militzer-Kopperl, 2022-12-15 The Roadmap to Literacy Renewal of Literacy Edition is a reading, writing, and language arts program for Waldorf schools grades 1-3. |
EXAMPLE Definition & Meaning - Merriam-Webster
The meaning of EXAMPLE is one that serves as a pattern to be imitated or not to be imitated. How to use example in a sentence. Synonym Discussion of Example.
EXAMPLE | English meaning - Cambridge Dictionary
EXAMPLE definition: 1. something that is typical of the group of things that it is a member of: 2. a way of helping…. Learn more.
EXAMPLE Definition & Meaning | Dictionary.com
one of a number of things, or a part of something, taken to show the character of the whole. This painting is an example of his early work. a pattern or model, as of something to be imitated or …
Example - definition of example by The Free Dictionary
1. one of a number of things, or a part of something, taken to show the character of the whole. 2. a pattern or model, as of something to be imitated or avoided: to set a good example. 3. an …
Example Definition & Meaning - YourDictionary
To be illustrated or exemplified (by). Wear something simple; for example, a skirt and blouse.
EXAMPLE - Meaning & Translations | Collins English Dictionary
An example of something is a particular situation, object, or person which shows that what is being claimed is true. 2. An example of a particular class of objects or styles is something that …
example noun - Definition, pictures, pronunciation and usage …
used to emphasize something that explains or supports what you are saying; used to give an example of what you are saying. There is a similar word in many languages, for example in …
Example - Definition, Meaning & Synonyms - Vocabulary.com
An example is a particular instance of something that is representative of a group, or an illustration of something that's been generally described. Example comes from the Latin word …
example - definition and meaning - Wordnik
noun Something that serves as a pattern of behaviour to be imitated (a good example) or not to be imitated (a bad example). noun A person punished as a warning to others. noun A parallel …
EXAMPLE Synonyms: 20 Similar Words - Merriam-Webster
Some common synonyms of example are case, illustration, instance, sample, and specimen. While all these words mean "something that exhibits distinguishing characteristics in its …
EXAMPLE Definition & Meaning - Merriam-Webster
The meaning of EXAMPLE is one that serves as a pattern to be imitated or not to be imitated. How to use example in a sentence. Synonym Discussion of Example.
EXAMPLE | English meaning - Cambridge Dictionary
EXAMPLE definition: 1. something that is typical of the group of things that it is a member of: 2. a way of helping…. Learn more.
EXAMPLE Definition & Meaning | Dictionary.com
one of a number of things, or a part of something, taken to show the character of the whole. This painting is an example of his early work. a pattern or model, as of something to be imitated or …
Example - definition of example by The Free Dictionary
1. one of a number of things, or a part of something, taken to show the character of the whole. 2. a pattern or model, as of something to be imitated or avoided: to set a good example. 3. an …
Example Definition & Meaning - YourDictionary
To be illustrated or exemplified (by). Wear something simple; for example, a skirt and blouse.
EXAMPLE - Meaning & Translations | Collins English Dictionary
An example of something is a particular situation, object, or person which shows that what is being claimed is true. 2. An example of a particular class of objects or styles is something that …
example noun - Definition, pictures, pronunciation and usage …
used to emphasize something that explains or supports what you are saying; used to give an example of what you are saying. There is a similar word in many languages, for example in …
Example - Definition, Meaning & Synonyms - Vocabulary.com
An example is a particular instance of something that is representative of a group, or an illustration of something that's been generally described. Example comes from the Latin word …
example - definition and meaning - Wordnik
noun Something that serves as a pattern of behaviour to be imitated (a good example) or not to be imitated (a bad example). noun A person punished as a warning to others. noun A parallel …
EXAMPLE Synonyms: 20 Similar Words - Merriam-Webster
Some common synonyms of example are case, illustration, instance, sample, and specimen. While all these words mean "something that exhibits distinguishing characteristics in its …
