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William Hyde Wollaston made an astonishing number of discoveries in an astonishingly varied number of fields: platinum metallurgy, the existence of ultraviolet radiation, the chemical elements palladium and rhodium, the amino acid cystine, and the physiology of binocular vision, among others. Along with his colleagues Humphry Davy and Thomas Young, he was widely recognized during his life as one of Britain’s leading scientific practitioners in the first part of the nineteenth century, and the deaths of all three within a six-month span, between 1828 and 1829, were seen by many as the end of a glorious period of British scientific supremacy. Unlike Davy and Young, however, Wollaston was not...
William Hyde Wollaston was born into a large, religious, and scientifically informed family in 1766 and died sixty-two years later as one of the Western world s most highly regarded scientists. With encouragement from his well-connected father, he studied medicine at Cambridge, and began practicing as a physician in the provinces before moving his practice to London in 1797, arriving in the capital about the same time as his illustrious colleagues Humphry Davy and Thomas Young. After a few years in London, Wollaston abandoned the vocation he had come to dislike and bravely set out to make his living as a chemical entrepreneur, while pursuing his intellectual interests in a wide range of cont...
The development of chemistry, like that of the other fields of science and technology, has depended greatly upon the availability of instruments. Accordingly, the study of the history of instrumentation is a major area in any survey of the progress in this science. Recognizing this fact, the Division of the History of Chemistry of the American Chemical Society organized and held a very successful symposium on the history of chemical instrumentation during the Washington, D.C. National Meeting in 1979. Re~arks, both formal and informal, made during this symposium stressed points that soon become obvious to anyone who looks at the ancestry of present-day instruments . In some cases, the total history is measured in years, rather than in centuries . Chemical instrumentation, by no means confined to the laboratory, is vital in industry. There is a natural tendency to discard an item of any kind when a newer version is acquired. Often, "to discard" means "to scrap". If the item scrapped is an instrument that is unique - sometimes the last of its kind - we have a permanent artefactual gap in the history of science.
A story of alchemy in Bohemian Paris, where two scientific outcasts discovered a fundamental distinction between natural and synthetic chemicals that inaugurated an enduring scientific mystery. For centuries, scientists believed that living matter possessed a special quality—a spirit or essence—that differentiated it from nonliving matter. But by the nineteenth century, the scientific consensus was that the building blocks of one were identical to the building blocks of the other. Elixir tells the story of two young chemists who were not convinced, and how their work rewrote the boundary between life and nonlife. In the 1830s, Édouard Laugier and Auguste Laurent were working in Laugier ...
Known as the 'father' of electrical engineering, Michael Faraday is one of the best known scientific figures of all time. In this Very Short Introduction, Frank A.J.L James looks at Faraday's life and works, examining the institutional context in which he lived and worked, his scientific research, and his continuing legacy in science today.
This volume moves chemical instruments and experiments into the foreground of historical concern, in line with the emphasis on practice that characterizes current work on other fields of science and engineering.
Accessible exploration of the noteworthy scientific career of James Smithson, who left his fortune to establish the Smithsonian Institution. James Smithson is best known as the founder of the Smithsonian Institution, but few people know his full and fascinating story. He was a widely respected chemist and mineralogist and a member of the Royal Society, but in 1865, his letters, collection of 10,000 minerals, and more than 200 unpublished papers were lost to a fire in the Smithsonian Castle. His scientific legacy was further written off as insignificant in an 1879 essay published through the Smithsonian fifty years after his death--a claim that author Steven Turner demonstrates is far from the truth. By providing scientific and intellectual context to his work, The Science of James Smithson is a comprehensive tribute to Smithson's contributions to his fields, including chemistry, mineralogy, and more. This detailed narrative illuminates Smithson and his quest for knowledge at a time when chemists still debated thing as basic as the nature of fire, and struggled to maintain their networks amid the ever-changing conditions of the French Revolution and the Napoleonic Wars.
Overlooked, even despised by historians of chemistry for many years, the genre of biography has enjoyed a revival since the beginning of this century. The key to its renaissance is the use of the biographical form to provide a contextual analysis of important themes in contrast to the uncritical, almost hagiographic, lives of chemists written in the earlier part of the twentieth century. Bringing together the contributions of scholars active in several different countries, Perspectives on Chemical Biography in the 21st Century leads the reader through emerging questions around sources, and the generic problems faced by authors of biographies, before moving on to discuss aspects more related with physical, theoretical and inorganic chemistry, and facets of 19th century chemistry. In contrast to the letters and diaries of earlier chemists, we are now faced with scientists who communicate by telephone and email, and compose their documents on computers. Are we facing a modern equivalent of the destruction of the Library of Alexandria where all our sources are wiped out electronically?
A compelling and innovative account that reshapes our view of nineteenth-century chemistry, explaining a critical period in chemistry’s quest to understand and manipulate organic nature. According to existing histories, theory drove chemistry’s remarkable nineteenth-century development. In Molecular World, Catherine M. Jackson shows instead how novel experimental approaches combined with what she calls “laboratory reasoning” enabled chemists to bridge wet chemistry and abstract concepts and, in so doing, create the molecular world. Jackson introduces a series of practice-based breakthroughs that include chemistry’s move into lampworked glassware, the field’s turn to synthesis and...
This work is the first explicit examination of the key role that mathematics has played in the development of theoretical physics and will undoubtedly challenge the more conventional accounts of its historical development. Although mathematics has long been regarded as the "language" of physics, the connections between these independent disciplines have been far more complex and intimate than previous narratives have shown. The author convincingly demonstrates that practices, methods, and language shaped the development of the field, and are a key to understanding the mergence of the modern academic discipline. Mathematicians and physicists, as well as historians of both disciplines, will find this provocative work of great interest.