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A collection of the Nobel Lectures delivered by the prizewinners in chemistry, together with their biographies, portraits and the presentation speeches.
James Chadwick (1891-1974) came from a humble background: his father was a cotton spinner. He was accepted in the physics department of Sir Ernest Rutherford at Manchester University in 1908 on a scholarship, and soon started publishing new findings about radioactivity. This led to a traveling scholarship to Berlin, where he made the important discovery of the continuous spectrum of β-particles. When the World War I broke out, Chadwick was interned by the Germans as an enemy alien for the next four years, but continued experiments in the prison camp. On his return to England in broken health, Rutherford invited Chadwick to join the Cavendish Laboratory in Cambridge where he became Rutherford’s deputy and oversaw much groundbreaking physics research over the next 15 years. Chadwick concentrated on finding evidence for the neutron, an uncharged nuclear particle whose existence was first proposed by Rutherford in 1920. Having noticed anomalous results from the Curie laboratory in Paris in 1932, Chadwick used simple bench-top apparatus to convince himself, after weeks of intense observations, that he had definite evidence for the existence of the neutron. The Nobel Prize for physics followed in 1935; that year he moved to Liverpool University to head his own department. At the outbreak of World War II, the feasibility of atomic bombs of unprecedented explosive power was already being discussed. Chadwick drafted the British MAUD committee's historic reports in the summer of 1941 which concluded that atomic bombs were indeed feasible with sufficient industrial capacity. In wartime Britain this was impossible, but in 1943 Chadwick moved to the US as head of the British scientists working on the Manhattan Project. He formed an unlikely alliance with its leader, General Leslie Groves, and became an adroit scientist-diplomat. Witnessing the first explosion of a plutonium-fueled device at the Trinity Test shattered him. Chadwick believed that dropping atomic bombs on Japanese cities was justified but the development of nuclear weapons as an unintended consequence of his discovery of the neutron caused him deep personal anguish. “Until this excellent book by Andrew Brown, [Chadwick] has remained the most shadowy of the atomic scientists who, for better or worse, gave the human species mastery over nuclear energy.” — Nigel Calder, New Scientist “Andrew Brown’s biography beautifully reveals [Chadwick’s] scientific, diplomatic and personal achievements.” — Roger H Stuewer, Physics Today “I can warmly recommend this book to all interested in the life of a remarkable scientist who played a crucial role in a formative period of the modern world.” — Hermann Bondi, Times Higher Education Supplement “This is the biography of a physicist who made one of the most important discoveries in nuclear physics, but retained to his old age the shyness of a young lad... Andrew Brown takes us through Chadwick’s life as an adventure... I found it a very good read.” — Hans Bethe, American Journal of Physics “The tale of so sterling a character, even when told as well as in this book, may be a little short on light moments, but any reader interested in the evolution of physics from an academic passion to a leading role on the world stage will find it a fascinating story and a worthy tribute to a great scientist.” — Brian Pippard, Nature “... makes absorbing reading... more than the life story of a remarkable man... unfolds the tremendous transformation that science underwent in the 20th century.” —Joseph Rotblat “… avidly researched and artfully written... This biography... blends elegantly direct scientific descriptions with often witty episodes and character summaries.” — William Lanouette, Bulletin of the Atomic Scientists
This volume is an important study for understanding the complex interconnections between basic science and its sources of economic support in the period between the two world wars. The focus of the study is on the Institute for Theoretical Physics (later renamed the Niels Bohr Institute) at Copenhagen University, and the role of its director, the eminent Danish physicist, Niels Bohr, in the funding and administration of the Institute. Under Bohr's direction, the Copenhagen Institute was a central workplace in the development and the formulation of quantum mechanics in the 1920s and later became an important center for nuclear research in the 1930s. Dr. Aaserud brings together the scholarhip on the internal origins and development of nuclear physics in the 1930s with descriptions of the concurrent changes in private support for international basic science, particularly as represented by Rockefeller Foundation philanthropy. In the process, the book places the emergence of nuclear physics in a larger historical context. This book will appeal to historians of science, physicists, and advanced students in these areas.
Describes Michael Polanyi's role in the way the philosophy of science was seen as a social enterprise, not relying entirely on empiricism and reason alone.
In this volume, a distinguished set of international scholars examine the nature of collaboration between life partners in the sciences, with particular attention to the ways in which personal and professional dynamics can foster or inhibit scientific practice. Breaking from traditional gender analyses which focus on divisions of labor and the assignment of credit, the studies scrutinize collaboration as a variable process between partners living in the nineteenth and twentieth centuries who were married and divorced, heterosexual and homosexual, aristocratic and working-class and politically right and left. The contributors analyze cases shaped by their particular geographical locations, ranging from retreat settings like the English countryside and Woods Hole, Massachusetts, to university laboratories and urban centers in Berlin, Stockholm, Geneva and London. The volume demonstrates how the terms and meanings of collaboration, variably shaped by disciplinary imperatives, cultural mores, and the agency of the collaborators themselves, illuminate critical intellectual and institutional developments in the modern sciences.
Business-to-business (B2B) integration is a buzzword which has been used a lot in recent years, with a variety of meanings. Starting with a clear technical definition of this term and its relation to topics like A2A (Application-to-Application), ASP (Application Service Provider), A2A, and B2C (Business-to-Consumer), Christoph Bussler outlines a complete and consistent B2B integration architecture based on a coherent conceptual model. He shows that B2B integration not only requires the exchange of business events between distributed trading partners across networks like the Internet, but also demands back-end application integration within business processes, and thus goes far beyond traditional approaches to enterprise application integration approaches. His detailed presentation describes how B2B integration standards like RosettaNet or SWIFT, the application integration standard J2EE Connector Architecture and basic standards like XML act together in order to enable business process integration. The book is the first of its kind that discusses B2B concepts and architectures independent of specific and short-term industrial or academic approaches and thus provides solid and long-lasting knowledge for researchers, students, and professionals interested in the field of B2B integration.
The story of the false entries, good-faith errors, retractions, and mistakes that occurred during the formation of the Periodic Table of Elements as we know it.
In this brief, Mary Virginia Orna details the history of color from the chemical point of view. Beginning with the first recorded uses of color and ending in the development of our modern chemical industry, this rich, yet concise exposition shows us how color pervades every aspect of our lives. Our consciousness, our perceptions, our useful appliances and tools, our playthings, our entertainment, our health, and our diagnostic apparatus – all involve color and are based in no small part on chemistry.
In Cathedrals of Science, Patrick Coffey describes how chemistry got its modern footing-how thirteen brilliant men and one woman struggled with the laws of the universe and with each other. They wanted to discover how the world worked, but they also wanted credit for making those discoveries, and their personalities often affected how that credit was assigned. Gilbert Lewis, for example, could be reclusive and resentful, and his enmity with Walther Nernst may have cost him the Nobel Prize; Irving Langmuir, gregarious and charming, "rediscovered" Lewis's theory of the chemical bond and received much of the credit for it. Langmuir's personality smoothed his path to the Nobel Prize over Lewis. Coffey deals with moral and societal issues as well. These same scientists were the first to be seen by their countries as military assets. Fritz Haber, dubbed the "father of chemical warfare," pioneered the use of poison gas in World War I-vividly described-and Glenn Seaborg and Harold Urey were leaders in World War II's Manhattan Project; Urey and Linus Pauling worked for nuclear disarmament after the war. Science was not always fair, and many were excluded. The Nazis pushed Jewish scientists like Haber from their posts in the 1930s. Anti-Semitism was also a force in American chemistry, and few women were allowed in; Pauling, for example, used his influence to cut off the funding and block the publications of his rival, Dorothy Wrinch. Cathedrals of Science paints a colorful portrait of the building of modern chemistry from the late 19th to the mid-20th century.