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This broad collection of accessible essays helps readers develop a fuller appreciation of the nature of science and scientific knowledge in general. The focus throughout is on the relationships in science between fact and theory, about the nature of scientific theory, and about the kinds of claims on truth that science makes. Arranges essays according to three essential aspects of scientific practice: Method, theory, and discovery. For scientists looking to broaden their general knowledge of basic scientific theory.
This classic MUP text discusses the historical development of science, technology and medicine in Western Europe and North America from the Renaissance to the present. Combining theoretical discussion and empirical illustration, it redefines the geography of science, technology and medicine.
One of the pathways by which the scientific community confirms the validity of a new scientific discovery is by repeating the research that produced it. When a scientific effort fails to independently confirm the computations or results of a previous study, some fear that it may be a symptom of a lack of rigor in science, while others argue that such an observed inconsistency can be an important precursor to new discovery. Concerns about reproducibility and replicability have been expressed in both scientific and popular media. As these concerns came to light, Congress requested that the National Academies of Sciences, Engineering, and Medicine conduct a study to assess the extent of issues related to reproducibility and replicability and to offer recommendations for improving rigor and transparency in scientific research. Reproducibility and Replicability in Science defines reproducibility and replicability and examines the factors that may lead to non-reproducibility and non-replicability in research. Unlike the typical expectation of reproducibility between two computations, expectations about replicability are more nuanced, and in some cases a lack of replicability can aid the process of scientific discovery. This report provides recommendations to researchers, academic institutions, journals, and funders on steps they can take to improve reproducibility and replicability in science.
A powerful exploration of diverse world views long ignored by the Western world that suggests possible solutions to the environmental and social problems that face us in the next millennium. Our civilization is in crisis. Overpopulation and overconsumption have jeopardized our survival and the great promises of technology have resulted in environmental disaster. This situation, says author John Broomfield, results from the serious error the Western world makes in equating one way of knowing with all ways of knowing--mistaking a thin slice of reality for the whole. Broomfield argues that the necessary wisdom to chart a new course is available to us from many sources: the sacred traditions of our ancestors; the spiritual traditions of other cultures; spirit in nature; feminine ways of being; contemporary movements for personal, social, and ecological transformation; and the very source of our current crisis, science itself. Other Ways of Knowing shows us the wisdom of other cultures who may hold the knowledge necessary to arrest our headlong race toward destruction. From the ancient Polynesian navigational technique of remote viewing to the formative causation theory of Rupert Sheldrake, Other Ways of Knowing examines perceptions and practices that challenge the narrow perspective of the Western world and provide answers to the complex questions that face us as we move into the next millennium.
This book provides a comprehensive overview of humanistic approaches to science. Approaches that connect students to broader human concerns in their everyday life and culture. Glen Aikenhead, an expert in the field of culturally sensitive science education, summarizes major worldwide historical findings; focuses on present thinking; and offers evidence in support of classroom practice. This highly accessible text covers curriculum policy, teaching materials, teacher orientations, teacher education, student learning, culture studies, and future research.
Notes on contributors Acknowledgements 1. The Idiom of Co-production Sheila Jasanoff 2. Ordering Knowledge, Ordering Society Sheila Jasanoff 3. Climate Science and the Making of a Global Political Order Clark A. Miller 4. Co-producing CITES and the African Elephant Charis Thompson 5. Knowledge and Political Order in the European Environment Agency Claire Waterton and Brian Wynne 6. Plants, Power and Development: Founding the Imperial Department of Agriculture for the West Indies, 1880-1914 William K. Storey 7. Mapping Systems and Moral Order: Constituting property in genome laboratories Stephen Hilgartner 8. Patients and Scientists in French Muscular Dystrophy Research Vololona Rabeharisoa and Michel Callon 9. Circumscribing Expertise: Membership categories in courtroom testimony Michael Lynch 10. The Science of Merit and the Merit of Science: Mental order and social order in early twentieth-century France and America John Carson 11. Mysteries of State, Mysteries of Nature: Authority, knowledge and expertise in the seventeenth century Peter Dear 12. Reconstructing Sociotechnical Order: Vannevar Bush and US science policy Michael Aaron Dennis 13. Science and the Political Imagination in Contemporary Democracies Yaron Ezrah 14. Afterword Sheila Jasanoff References Index
“The Knowledge Machine is the most stunningly illuminating book of the last several decades regarding the all-important scientific enterprise.” —Rebecca Newberger Goldstein, author of Plato at the Googleplex A paradigm-shifting work, The Knowledge Machine revolutionizes our understanding of the origins and structure of science. • Why is science so powerful? • Why did it take so long—two thousand years after the invention of philosophy and mathematics—for the human race to start using science to learn the secrets of the universe? In a groundbreaking work that blends science, philosophy, and history, leading philosopher of science Michael Strevens answers these challenging questions, showing how science came about only once thinkers stumbled upon the astonishing idea that scientific breakthroughs could be accomplished by breaking the rules of logical argument. Like such classic works as Karl Popper’s The Logic of Scientific Discovery and Thomas Kuhn’s The Structure of Scientific Revolutions, The Knowledge Machine grapples with the meaning and origins of science, using a plethora of vivid historical examples to demonstrate that scientists willfully ignore religion, theoretical beauty, and even philosophy to embrace a constricted code of argument whose very narrowness channels unprecedented energy into empirical observation and experimentation. Strevens calls this scientific code the iron rule of explanation, and reveals the way in which the rule, precisely because it is unreasonably close-minded, overcomes individual prejudices to lead humanity inexorably toward the secrets of nature. “With a mixture of philosophical and historical argument, and written in an engrossing style” (Alan Ryan), The Knowledge Machine provides captivating portraits of some of the greatest luminaries in science’s history, including Isaac Newton, the chief architect of modern science and its foundational theories of motion and gravitation; William Whewell, perhaps the greatest philosopher-scientist of the early nineteenth century; and Murray Gell-Mann, discoverer of the quark. Today, Strevens argues, in the face of threats from a changing climate and global pandemics, the idiosyncratic but highly effective scientific knowledge machine must be protected from politicians, commercial interests, and even scientists themselves who seek to open it up, to make it less narrow and more rational—and thus to undermine its devotedly empirical search for truth. Rich with illuminating and often delightfully quirky illustrations, The Knowledge Machine, written in a winningly accessible style that belies the import of its revisionist and groundbreaking concepts, radically reframes much of what we thought we knew about the origins of the modern world.
In recent history, the arts and sciences have often been considered opposing fields of study, but a growing trend in drawing research is beginning to bridge this divide. Gemma Anderson’s Drawing as a Way of Knowing in Art and Science introduces tested ways in which drawing as a research practice can enhance morphological insight, specifically within the natural sciences, mathematics and art. Inspired and informed by collaboration with contemporary scientists and Goethe’s studies of morphology, as well as the work of artist Paul Klee, this book presents drawing as a means of developing and disseminating knowledge, and of understanding and engaging with the diversity of natural and theoretical forms, such as animal, vegetable, mineral and four dimensional shapes. Anderson shows that drawing can offer a means of scientific discovery and can be integral to the creation of new knowledge in science as well as in the arts.
In 1991, when her daughter’s rare, hand-carved harp was stolen, Lisby Mayer’s familiar world of science and rational thinking turned upside down. After the police failed to turn up any leads, a friend suggested she call a dowser—a man who specialized in finding lost objects. With nothing to lose—and almost as a joke—Dr. Mayer agreed. Within two days, and without leaving his Arkansas home, the dowser located the exact California street coordinates where the harp was found. Deeply shaken, yet driven to understand what had happened, Mayer began the fourteen-year journey of discovery that she recounts in this mind-opening, brilliantly readable book. Her first surprise: the dozens of colleagues who’d been keeping similar experiences secret for years, fearful of being labeled credulous or crazy. Extraordinary Knowing is an attempt to break through the silence imposed by fear and to explore what science has to say about these and countless other “inexplicable” phenomena. From Sigmund Freud’s writings on telepathy to secret CIA experiments on remote viewing, from leading-edge neuroscience to the strange world of quantum physics, Dr. Mayer reveals a wealth of credible and fascinating research into the realm where the mind seems to trump the laws of nature. She does not ask us to believe. Rather she brings us a book of profound intrigue and optimism, with far-reaching implications not just for scientific inquiry but also for the ways we go about living in the world.
We are accustomed to thinking of science and its findings as universal. After all, one atom of carbon plus two of oxygen yields carbon dioxide in Amazonia as well as in Alaska; a scientist in Bombay can use the same materials and techniques to challenge the work of a scientist in New York; and of course the laws of gravity apply worldwide. Why, then, should the spaces where science is done matter at all? David N. Livingstone here puts that question to the test with his fascinating study of how science bears the marks of its place of production. Putting Science in Its Place establishes the fundamental importance of geography in both the generation and the consumption of scientific knowledge, using historical examples of the many places where science has been practiced. Livingstone first turns his attention to some of the specific sites where science has been made—the laboratory, museum, and botanical garden, to name some of the more conventional locales, but also places like the coffeehouse and cathedral, ship's deck and asylum, even the human body itself. In each case, he reveals just how the space of inquiry has conditioned the investigations carried out there. He then describes how, on a regional scale, provincial cultures have shaped scientific endeavor and how, in turn, scientific practices have been instrumental in forming local identities. Widening his inquiry, Livingstone points gently to the fundamental instability of scientific meaning, based on case studies of how scientific theories have been received in different locales. Putting Science in Its Place powerfully concludes by examining the remarkable mobility of science and the seemingly effortless way it moves around the globe. From the reception of Darwin in the land of the Maori to the giraffe that walked from Marseilles to Paris, Livingstone shows that place does matter, even in the world of science.