Whether in the context of off-shore oil exploration or pure research, the oceans of the geological past have never been of more compelling interest. The recent expansion in oceanographic studies has produced a burgeoning of data on ancient ocean circulation, climate, bathymetry, chemistry, biology, and temperature data that now should be considered in a more general geological and paleontological framework.

Schopf has produced a remarkable synthesis of these data that provides any earth scientist with the background necessary to appreciate the history of the ancient oceans. Each of his seven chapters includes a summary of modern conditions, a major section on methods for determining ancient patterns, and a summary of each oceanographic factor over geological time.

Paleoceanography will serve as an important resource for paleontologists and for a much broader audience of earth and ocean scientists, petroleum geologists, and stratigraphers.

From molecules to stars, much of the cosmic canvas can be painted in brushstrokes of primary color: the protons, neutrons, and electrons we know so well. But for meticulous detail, we have to dip into exotic hues—leptons, mesons, hadrons, quarks. Bringing particle physics to life as few authors can, Jeremy Bernstein here unveils nature in all its subatomic splendor.

In this graceful account, Bernstein guides us through high-energy physics from the early twentieth century to the present, including such highlights as the newly discovered Higgs boson. Beginning with Ernest Rutherford’s 1911 explanation of the nucleus, a model of atomic structure emerged that sufficed until the 1930s, when new particles began to be theorized and experimentally confirmed. In the postwar period, the subatomic world exploded in a blaze of unexpected findings leading to the theory of the quark, in all its strange and charmed variations. An eyewitness to developments at Harvard University and the Institute for Advanced Study in Princeton, Bernstein laces his story with piquant anecdotes of such luminaries as Wolfgang Pauli, Murray Gell-Mann, and Sheldon Glashow.

Surveying the dizzying landscape of contemporary physics, Bernstein remains optimistic about our ability to comprehend the secrets of the cosmos—even as its mysteries deepen. We now know that over eighty percent of the universe consists of matter we have never identified or detected. A Palette of Particles draws readers into the excitement of a field where the more we discover, the less we seem to know.

A scientist friend asked Bruno Latour point-blank: “Do you believe in reality?” Taken aback by this strange query, Latour offers his meticulous response in Pandora’s Hope. It is a remarkable argument for understanding the reality of science in practical terms.

In this book, Latour, identified by Richard Rorty as the new “bête noire of the science worshipers,” gives us his most philosophically informed book since Science in Action. Through case studies of scientists in the Amazon analyzing soil and in Pasteur’s lab studying the fermentation of lactic acid, he shows us the myriad steps by which events in the material world are transformed into items of scientific knowledge. Through many examples in the world of technology, we see how the material and human worlds come together and are reciprocally transformed in this process.

Why, Latour asks, did the idea of an independent reality, free of human interaction, emerge in the first place? His answer to this question, harking back to the debates between Might and Right narrated by Plato, points to the real stakes in the so-called science wars: the perplexed submission of ordinary people before the warring forces of claimants to the ultimate truth.

Leading evolutionary theorists and philosophers come together to understand how organisms persist, even as they’re riddled with internal conflict, from cancer cells to selfish genes.

How does a vast menagerie of organs, tissues, cells, and genes coalesce to form a unified organism? For centuries, biologists and philosophers have taken this astonishing feat for granted, treating it as a matter of divine will or evolutionary inevitability. Yet unity is hardly assured. From cancer cells to selfish genes, the body is riven by internal conflicts.

The Paradox of the Organism grapples with this puzzle. As the essays in this collection show, profound questions arise when we pierce the organismal veil and consider the self-replicating elements within. Is an organism really a cohesive agent that adapts to the ecosystem it inhabits? Or is an organism itself an ecosystem, within which individual components are engaged in a continuous arms race?

The answers have immediate implications: for understanding miscarriage, treating cancer, improving psychological health, and preserving biodiversity. Challenging fundamental precepts of evolutionary theory, The Paradox of the Organism offers an incisive account of life’s extraordinary success.

,The scientific correspondence of Watt, Black, Robison and others, together with James Watt's notebook of experiments on heat, edited by Eric Robinson and Douglas McKie.,

, The close friendship that grew up between Dr. Joseph Black, the,discoverer of specific and latent heats, and James Watt, the scientific instrument maker who was destined to become perhaps the greatest engineer of all time, is in,itself a dramatic relationship, not before fully appreciated, Here for the first time is the full text of all their surviving correspondence, known only fragmentarily before in J. P. Muirhead's Life and Mechanical Inventions of James Watt, and there rather freely amended by the editor.,

The amazing range of Watt's interests--in the firing of delft and stoneware, the manufacture of alkali from salt, the invention of scientific instruments as well as the copying press, and many other matters beside the steam-engine--is revealed here. Watt's own position as a scientist and the quality of his association with Black in further experiments on latent heat are fully documented. But the,correspondence is also valuable for the light it sheds on many aspects of life in Britain in the later half of the eighteenth century.

In addition, Watt's notebook on his experiments on heat, known before only through quotation, is presented complete. This is a primary source of first-rate importance to the historian of science.

Inductive zoology.

Aristotle, great Greek philosopher, researcher, reasoner, and writer, born at Stagirus in 384 BC, was the son of a physician. He studied under Plato at Athens and taught there (367–347); subsequently he spent three years at the court of a former pupil in Asia Minor. After some time at Mitylene, in 343–342 he was appointed by King Philip of Macedon to be tutor of his teen-aged son Alexander. After Philip’s death in 336, Aristotle became head of his own school (of “Peripatetics”), the Lyceum at Athens. Because of anti-Macedonian feeling there after Alexander’s death in 323, he withdrew to Chalcis in Euboea, where he died in 322.

Nearly all the works Aristotle prepared for publication are lost; the priceless ones extant are lecture-materials, notes, and memoranda (some are spurious). They can be categorized as follows:

I Practical: Nicomachean Ethics; Great Ethics (Magna Moralia); Eudemian Ethics; Politics; Economics (on the good of the family); On Virtues and Vices.
II Logical: Categories; Analytics (Prior and Posterior); Interpretation; Refutations used by Sophists; Topica.
III Physical: Twenty-six works (some suspect) including astronomy, generation and destruction, the senses, memory, sleep, dreams, life, facts about animals, etc.
IV Metaphysics: on being as being.
V Art: Rhetoric and Poetics.
VI Other works including the Constitution of Athens; more works also of doubtful authorship.
VII Fragments of various works such as dialogues on philosophy and literature; and of treatises on rhetoric, politics, and metaphysics.

The Loeb Classical Library edition of Aristotle is in twenty-three volumes.

Leona Marshall Libby was a pioneer in modern climatic research, a field that gained great impetus in the late twentieth century because of the promise it holds for predicting future climatic trends. Libby’s work led to remarkable new procedures for investigating long-term changes in precipitation and temperature and thereby greatly expanding our knowledge of past climates.

As Professor Rainer Berger writes in his foreword:

 “In recent years, tree ring–based temperature data have been collected which go far beyond the records available to historians. These data can be analyzed by Fourier transforms which identify certain periodicities. . . . Climatic changes detected by tree rings have been checked against historic records. . . . The correspondence is astonishing. . . .  

“At present weather forecasting is becoming more accurate for periods on the order of days, weeks, and months. Climatic prognoses have also been attempted for very long times of tens of thousands of years. But the intermediate range in the decades and centuries has so far been an enigma. It is here where tree ring thermometry plays its trump cards.

 “. . . Its potential is enormous in assessing worldwide crop yields, water inventory, heating requirements, stockpiling policies, and construction planning as well as political and military prospects.”

What can one man accomplish, even a great man and brilliant scientist? Although every town in France has a street named for Louis Pasteur, was he alone able to stop people from spitting, persuade them to dig drains, influence them to undergo vaccination? Pasteur’s success depended upon a whole network of forces, including the public hygiene movement, the medical profession (both military physicians and private practitioners), and colonial interests. It is the operation of these forces, in combination with the talent of Pasteur, that Bruno Latour sets before us as a prime example of science in action.

Latour argues that the triumph of the biologist and his methodology must be understood within the particular historical convergence of competing social forces and conflicting interests. Yet Pasteur was not the only scientist working on the relationships of microbes and disease. How was he able to galvanize the other forces to support his own research? Latour shows Pasteur’s efforts to win over the French public—the farmers, industrialists, politicians, and much of the scientific establishment.

Instead of reducing science to a given social environment, Latour tries to show the simultaneous building of a society and its scientific facts. The first section of the book, which retells the story of Pasteur, is a vivid description of an approach to science whose theoretical implications go far beyond a particular case study. In the second part of the book, “Irreductions,” Latour sets out his notion of the dynamics of conflict and interaction, of the “relation of forces.” Latour’s method of analysis cuts across and through the boundaries of the established disciplines of sociology, history, and the philosophy of science, to reveal how it is possible not to make the distinction between reason and force. Instead of leading to sociological reductionism, this method leads to an unexpected irreductionism.

“In this rigorous and beautifully researched volume, Milanich considers the tension between social and biological definitions of fatherhood, and shows how much we still have to learn about what constitutes a father.”
—Andrew Solomon, author of Far from the Tree: Parents, Children, and the Search for Identity

For most of human history, the notion that paternity was uncertain appeared to be an immutable law of nature. The unknown father provided entertaining plotlines from Shakespeare to the Victorian novelists and lay at the heart of inheritance and child support disputes. But in the 1920s new scientific advances promised to solve the mystery of paternity once and for all. The stakes were high: fatherhood has always been a public relationship as well as a private one. It confers not only patrimony and legitimacy but also a name, nationality, and identity.

The new science of paternity, with methods such as blood typing, fingerprinting, and facial analysis, would bring clarity to the conundrum of fatherhood—or so it appeared. Suddenly, it would be possible to establish family relationships, expose adulterous affairs, locate errant fathers, unravel baby mix-ups, and discover one’s true race and ethnicity. Tracing the scientific quest for the father up to the present, with the advent of seemingly foolproof DNA analysis, Nara Milanich shows that the effort to establish biological truth has not ended the quest for the father. Rather, scientific certainty has revealed the fundamentally social, cultural, and political nature of paternity. As Paternity shows, in the age of modern genetics the answer to the question “Who’s your father?” remains as complicated as ever.

Alfred V. Kidder’s excavations at Pecos Pueblo in New Mexico between 1914 and 1929 set a new standard for archaeological fieldwork and interpretation. Among his other innovations, Kidder recognized that skeletal remains were a valuable source of information, and today the Pecos sample is used in comparative studies of fossil hominins and recent populations alike.

In the 1990s, while documenting this historic collection in accordance with the Native American Graves Protection and Repatriation Act before the remains were returned to the Pueblo of Jemez and reinterred at Pecos Pueblo, Michèle E. Morgan and colleagues undertook a painstaking review of the field data to create a vastly improved database. The Peabody Museum, where the remains had been housed since the 1920s, also invited a team of experts to collaboratively study some of the materials.

In Pecos Pueblo Revisited, these scholars review some of the most significant findings from Pecos Pueblo in the context of current Southwestern archaeological and osteological perspectives and provide new interpretations of the behavior and biology of the inhabitants of the pueblo. The volume also presents improved data sets in extensive appendices that make the primary data available for future analysis. The volume answers many existing questions about the population of Pecos and other Rio Grande sites and will stimulate future analysis of this important collection.

This engaging and wide-ranging biography casts new light on the life and careers of Percival Lowell. Scion of a wealthy Boston family, elder brother of Harvard President Lawrence and poet Amy, Percival Lowell is best remembered as the astronomer who claimed that intelligent beings had built a network of canals on Mars. But the Lowell who emerges in David Strauss's finely textured portrait was a polymath: not just a self-taught astronomer, but a shrewd investor, skilled photographer, inspired public speaker, and adventure-travel writer whose popular books contributed to an awakening American interest in Japan.

Strauss shows that Lowell consistently followed the same intellectual agenda. One of the principal American disciples of Herbert Spencer, Lowell, in his investigations of Japanese culture, set out to confirm Spencer's notion that Westerners were the highest expression of the evolutionary process. In his brilliant defense of the canals on Mars, Lowell drew on Spencer's claim that planets would develop life-supporting atmospheres over time.

Strauss's charming, somewhat bittersweet tale is the story of a rebellious Boston Brahmin whose outsider mentality, deep commitment to personal freedom, and competence in two cultures all contributed to the very special character of his careers, first as a cultural analyst and then more memorably as an astronomer.

Almost weightless and able to pass through the densest materials with ease, neutrinos seem to defy the laws of nature. But these mysterious particles may hold the key to our deepest questions about the universe, says physicist Heinrich Päs. In The Perfect Wave, Päs serves as our fluent, deeply knowledgeable guide to a particle world that tests the boundaries of space, time, and human knowledge.

The existence of the neutrino was first proposed in 1930, but decades passed before one was detected. Päs animates the philosophical and scientific developments that led to and have followed from this seminal discovery, ranging from familiar topics of relativity and quantum mechanics to more speculative theories about dark energy and supersymmetry. Many cutting-edge topics in neutrino research--conjectures about the origin of matter, extra-dimensional spacetime, and the possibility of time travel--remain unproven. But Päs describes the ambitious projects under way that may confirm them, including accelerator experiments at CERN and Fermilab, huge subterranean telescopes designed to detect high-energy neutrino radiation, and the Planck space observatory scheduled to investigate the role of neutrinos in cosmic evolution.

As Päs's history of the neutrino illustrates, what is now established fact often sounded wildly implausible and unnatural when first proposed. The radical side of physics is both an exciting and an essential part of scientific progress, and The Perfect Wave renders it accessible to the interested reader.

A leading neuroscientist argues that the peripheral nervous system, long understood to play a key role in regulating basic bodily functions, also signals the onset of illness.

The central nervous system, consisting of the brain and the spinal cord, has long been considered the command center of the body. Yet outside the central nervous system, an elaborate network of nerve cells and fibers extends throughout our bodies, transmitting messages between the brain and other organs. The peripheral nervous system, as it’s known, regulates such vital functions as heart rate, digestion, and perspiration and enables us to experience the barrage of sounds, tastes, smells, and other sensory information that surrounds us. But beyond these crucial roles, the peripheral nervous system might do even more: it might warn us of diseases in our future.

As Moses Chao argues in Periphery, from Parkinson’s disease to autism to dementia, many neurological conditions emerge not in the brain but rather within the peripheral nervous system, in the dense network of nerves that wrap around the gastrointestinal tract. What’s more, dysfunctions of the peripheral nervous system can signal the onset of disease decades before symptoms like tremor or memory loss occur. Fortunately, unlike nerves in the brain and spinal cord, peripheral nerves can heal and regenerate in response to injury and aging. The therapeutic implications are remarkable. Chao shows how, with a better understanding of the peripheral nervous system, we could not only predict and treat neurological diseases long before their onset, but possibly prevent them altogether.

Full of new ideas and bold interpretations of the latest data, Periphery opens exciting avenues for medical research while deepening our understanding of a crucial yet underappreciated biological system.

Interdisciplinary voices reflect on some of the most complex and consequential scientific undertakings of our time

Perspectives on the Human Genome Project and Genomics is a groundbreaking volume that examines the pivotal roles of the National Institutes of Health (NIH) and the National Human Genome Research Institute (NHGRI) in the Human Genome Project (HGP) and the development of other major genomics projects. Drawing on newly uncovered archival materials and oral histories from NHGRI, this volume offers a multifaceted narrative of some of the most transformative scientific achievements of the twentieth and twenty-first centuries.

Coeditors Christopher R. Donohue and Alan C. Love bring together a range of perspectives on the HGP’s progress and legacy, as well as other major genomics projects, to explore not only their scientific achievements but also their social and political dimensions. Presenting reflections from historians, philosophers, and sociologists alongside those of key NHGRI scientists like Eric Green, Mark Guyer, and Elise Feingold; experts like Nature editor-in-chief Magdalena Skipper and geneticist Eric Vilain; and scholars of the ethical, legal, and social implications of genomics like Jean McEwan and Joy Boyer, Perspectives on the Human Genome Project and Genomics highlights the international, interdisciplinary collaborations and collective long view that underpinned these genomics initiatives aimed at a better understanding of our basic biology and genetic diseases.

From genomic variation and sequencing technologies to the integration of big data and the influence of ancestry and gender, this book is an essential resource for deepening the discussion of the scientific, historical, and ethical impacts of genomics and a fascinating collection of insights into coordinated science in the making.

Contributors: Rina Bliss, Joy Boyer, Lisa D. Brooks, Michel Dubois, Elise A. Feingold, Adam Felsenfeld, Miguel García-Sancho, Eric Green, Catherine Guaspare, Chris Gunter, Stephan Guttinger, Mark Guyer, Elke Jordan, Jonathan E. LoTempio Jr., Jean McEwen, Jane Peterson, Anya Plutynski, Ramya M. Rajagopalan, Emanuele Ratti, Sahotra Sarkar, Jeffery A. Schloss, Magdalena Skipper, Alexandra Soulier, Thomas Stoeger, Eric Vilain, Kris A. Wetterstrand.

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The surprising roles of instruments and experimentation in acquiring knowledge

In Philosophical Instruments Daniel Rothbart argues that our tools are not just neutral intermediaries between humans and the natural world, but are devices that demand new ideas about reality. Just as a hunter's new spear can change their knowledge of the environment, so can the development of modern scientific equipment alter our view of the world.

Working at the intersections of science, technology, and philosophy, Rothbart examines the revolution in knowledge brought on by recent advances in scientific instruments. Full of examples from historical and contemporary science, including electron scanning microscopes, sixteenth-century philosophical instruments, and diffraction devices used by biochemical researchers, Rothbart explores the ways in which instrumentation advances a philosophical stance about an instrument's power, an experimenter's skills, and a specimen's properties. Through a close reading of engineering of instruments, he introduces a philosophy from (rather than of) design, contending that philosophical ideas are channeled from design plans to models and from model into the use of the devices.

Hilary Putnam’s unceasing self-criticism has led to the frequent changes of mind he is famous for, but his thinking is also marked by considerable continuity. A simultaneous interest in science and ethics—unusual in the current climate of contention—has long characterized his thought. In Philosophy in an Age of Science, Putnam collects his papers for publication—his first volume in almost two decades.

Mario De Caro and David Macarthur’s introduction identifies central themes to help the reader negotiate between Putnam past and Putnam present: his critique of logical positivism; his enduring aspiration to be realist about rational normativity; his anti-essentialism about a range of central philosophical notions; his reconciliation of the scientific worldview and the humanistic tradition; and his movement from reductive scientific naturalism to liberal naturalism. Putnam returns here to some of his first enthusiasms in philosophy, such as logic, mathematics, and quantum mechanics. The reader is given a glimpse, too, of ideas currently in development on the subject of perception.

Putnam’s work, contributing to a broad range of philosophical inquiry, has been said to represent a “history of recent philosophy in outline.” Here it also delineates a possible future.

Phylogeography is a discipline concerned with various relationships between gene genealogies—phylogenetics—and geography. The word “phylogeography” was coined in 1987, and since then the scientific literature has reflected an exploding interest in the topic. Yet, to date, no book-length treatment of this emerging field has appeared. Phylogeography: The History and Formation of Species fills that gap.

The study of phylogeography grew out of the observation that mitochondrial DNA lineages in natural populations often display distinct geographic orientations. In recent years, the field has expanded to include assessments of nuclear as well as cytoplasmic genomes and the relationships among gene trees, population demography, and organismal history, often formalized as coalescent theory. Phylogeography has connections to molecular evolutionary genetics, natural history, population biology, paleontology, historical geography, and speciation analysis.

Phylogeography captures the conceptual and empirical richness of the field, and also the sense of genuine innovation that phylogeographic perspectives have brought to evolutionary studies. This book will be essential reading for graduate students and professionals in evolutionary biology and ecology as well as for anyone interested in the emergence of this new and integrative discipline.

This magnificent account of the coming of age of physics in America has been heralded as the best introduction to the history of science in the United States. Unsurpassed in its breadth and literary style, Daniel J. Kevles’s account portrays the brilliant scientists who became a powerful force in bringing the world into a revolutionary new era. The book ranges widely as it links these exciting developments to the social, cultural, and political changes that occurred from the post–Civil War years to the present. Throughout, Kevles keeps his eye on the central question of how an avowedly elitist enterprise grew and prospered in a democratic culture.

In this new edition, the author has brought the story up-to-date by providing an extensive, authoritative, and colorful account of the Superconducting Super Collider, from its origins in the international competition and intellectual needs of high-energy particle physics, through its establishment as a multibillion-dollar project, to its termination, in 1993, as a result of angry opposition within the American physics community and Congress.