This volume aims to attract attention to the necessity for quality advice on science and technology issues to the president of the United States, to the Congress, and to the judiciary. It emphasizes reconsideration and improvement of existing organizations and mechanisms, mindful of the need to adapt to changing circumstances. Golden has gathered facts and opinions useful to a wide range of people: government officials and staffs in all three branches; journalists; scholars and students of political science, science policy, and the history of science policy; members of the industrial and financial communities; and the concerned citizenry. The eighty-five prominent experts include both of President Reagan's science advisors, President Gerald R. Ford, congressional leaders, and distinguished members of the judiciary.
First published in 1990. The contributors discuss the organizations for provision of science and technology advice to the highest levels of governments of some 35 countries, including major countries of the world and a selection of important smaller countries. Inclusion of some communist and developing countries adds piquancy. The papers comment on functioning of those organizations as well as describe their formal structure. Each author was asked to describe the science and technology advising organizations for the highest level of his or her country's government and comment on its effectiveness and how it influences policy formulation and action.
The elimination of the Office of Technology Assessment (OTA) in 1995 came during a storm of budget cutting and partisan conflict. Operationally, it left Congress without an institutional arrangement to bring expert scientific and technological advice into the process of legislative decisionmaking. This deficiency has become increasingly critical, as more and more of the decisions faced by Congress and society require judgments based on highly specialized technical information. Offering perspectives from scholars and scientists with diverse academic backgrounds and extensive experience within the policy process, Science and Technology Advice for Congress breaks from the politics of the OTA and its contentious aftermath. Granger Morgan and Jon Peha begin with an overview of the use of technical information in framing policy issues, crafting legislation, and the overall process of governing. They note how, as nonexperts, legislators must make decisions in the face of scientific uncertainty and competing scientific claims from stakeholders. The contributors continue with a discussion of why OTA was created. They draw lessons from OTA's demise, and compare the use of science and technological information in Europe with the United States. The second part of the book responds to requests from congressional leaders for practical solutions. Among the options discussed are expanded functions within existing agencies such as the General Accounting or Congressional Budget Offices; an independent, NGO- administrated analysis group; and a dedicated successor to OTA within Congress. The models emphasize flexibility--and the need to make political feasibility a core component of design.
Assessing the influence of scientific advice in societies that increasingly question scientific authority and expertise. Today, scientific advice is asked for (and given) on questions ranging from stem-cell research to genetically modified food. And yet it often seems that the more urgently scientific advice is solicited, the more vigorously scientific authority is questioned by policy makers, stakeholders, and citizens. This book examines a paradox: how scientific advice can be influential in society even when the status of science and scientists seems to be at a low ebb. The authors do this by means of an ethnographic study of the creation of scientific authority at one of the key sites for the interaction of science, policy, and society: the scientific advisory committee. The Paradox of Scientific Authority offers a detailed analysis of the inner workings of the influential Health Council of the Netherlands (the equivalent of the National Academy of Science in the United States), examining its societal role as well as its internal functioning, and using the findings to build a theory of scientific advising. The question of scientific authority has political as well as scholarly relevance. Democratic political institutions, largely developed in the nineteenth century, lack the institutional means to address the twenty-first century's pervasively scientific and technological culture; and science and technology studies (STS) grapples with the central question of how to understand the authority of science while recognizing its socially constructed nature.
Behind today's headlines stands an unobtrusive army of science advisors—panels of scientific, medical, and engineering experts evaluate the safety of the food we eat, the drugs we take, and the cars we drive. This book studies, theoretically and empirically, the social process through which the credibility of expert advice is produced, challenged, and sustained.
Wall Street Journal, USA Today, and Publishers Weekly bestseller The prospect of living to 200 years old isn’t science fiction anymore. A leader in the emerging field of longevity offers his perspective on what cutting-edge breakthroughs are on the horizon, as well as the practical steps we can take now to live healthily to 100 and beyond. In The Science and Technology of Growing Young, industry investor and insider Sergey Young demystifies the longevity landscape, cutting through the hype and showing readers what they can do now to live better for longer, and offering a look into the exciting possibilities that await us. By viewing aging as a condition that can be cured, we can dramatically revolutionize the field of longevity and make it accessible for everyone. Join Sergey as he gathers insights from world-leading health entrepreneurs, scientists, doctors, and inventors, providing a comprehensive look into the future of longevity in two horizons: • The Near Horizon of Longevity identifies the technological developments that will allow us to live to 150—some of which are already in use—from AI-based diagnostics to gene editing and organ regeneration. • The Far Horizon of Longevity offers a tour of the future of age reversal, and the exciting technologies that will allow us to live healthily to 200, from Internet of Bodies to digital avatars to AI-brain integration. In a bonus chapter, Sergey also showcases 10 longevity choices that we already know and can easily implement to live to 100, distilling the science behind diet, exercise, sleep, mental health, and our environments into attainable habits and lifestyle hacks that anyone can adopt to vastly improve their lives and workplaces. Combining practical advice with an incredible overview of the brave new world to come, The Science and Technology of Growing Young redefines what it means to be human and to grow young.
An anecdotal guide for the perplexed new investigator as well as a refreshing resource for the old pro, covering everything from valuable personality traits for an investigator to social factors conducive to scientific work. Santiago Ramón y Cajal was a mythic figure in science. Hailed as the father of modern anatomy and neurobiology, he was largely responsible for the modern conception of the brain. His groundbreaking works were New Ideas on the Structure of the Nervous System and Histology of the Nervous System in Man and Vertebrates. In addition to leaving a legacy of unparalleled scientific research, Cajal sought to educate the novice scientist about how science was done and how he thought it should be done. This recently rediscovered classic, first published in 1897, is an anecdotal guide for the perplexed new investigator as well as a refreshing resource for the old pro. Cajal was a pragmatist, aware of the pitfalls of being too idealistic—and he had a sense of humor, particularly evident in his diagnoses of various stereotypes of eccentric scientists. The book covers everything from valuable personality traits for an investigator to social factors conducive to scientific work.
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.
This report contains a collection of papers from a workshopâ€"Strengthening Science-Based Decision-Making for Sustainable Management of Scarce Water Resources for Agricultural Production, held in Tunisia. Participants, including scientists, decision makers, representatives of non-profit organizations, and a farmer, came from the United States and several countries in North Africa and the Middle East. The papers examined constraints to agricultural production as it relates to water scarcity; focusing on 1) the state of the science regarding water management for agricultural purposes in the Middle East and North Africa 2) how science can be applied to better manage existing water supplies to optimize the domestic production of food and fiber. The cross-cutting themes of the workshop were the elements or principles of science-based decision making, the role of the scientific community in ensuring that science is an integral part of the decision making process, and ways to improve communications between scientists and decision makers.
