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A history of the 1702 chair in chemistry at the University of Cambridge.
Texts of the past were often not monolingual but were produced by and for people with bi- or multilingual repertoires; the communicative practices witnessed in them therefore reflect ongoing and earlier language contact situations. However, textbooks and earlier research tend to display a monolingual bias. This collected volume on multilingual practices in historical materials, including code-switching, highlights the importance of a multilingual approach. The authors explore multilingualism in hitherto neglected genres, periods and areas, introduce new methods of locating and analysing multiple languages in various sources, and review terminology, theories and tools. The studies also revisit some of the issues already introduced in previous research, such as Latin interacting with European vernaculars and the complex relationship between code-switching and lexical borrowing. Collectively, the contributors show that multilingual practices share many of the same features regardless of time and place, and that one way or the other, all historical texts are multilingual. This book takes the next step in historical multilingualism studies by establishing the relevance of the multilingual approach to understanding language history.
White coats, Bunsen burners, beakers, flasks, and pipettes—the furnishings of the chemistry laboratory are familiar to most of us from our school days, but just how did these items come to be the crucial tools of science? Examining the history of the laboratory, Peter J. T. Morris offers a unique way to look at the history of chemistry itself, showing how the development of the laboratory helped shape modern chemistry. Chemists, Morris shows, are one of the leading drivers of innovation in laboratory design and technology. He tells of fascinating lineages of invention and innovation, for instance, how the introduction of coal gas into Robert Wilhelm Bunsen’s laboratory led to the eponymous burner, which in turn led to the development of atomic spectroscopy. Comparing laboratories across eras, from the furnace-centered labs that survived until the late eighteenth century to the cleanrooms of today, he shows how the overlooked aspects of science—the architectural design and innovative tools that have facilitated its practice—have had a profound impact on what science has been able to do and, ultimately, what we have been able to understand.
Volume XXI/2 of History of Universities contains the customary mix of learned articles, book reviews, conference reports, and bibliographical information, which makes this publication such an indispensable tool for the historian of higher education. Its contributions range widely geographically, chronologically, and in subject-matter. The volume is, as always, a lively combination of original research and invaluable reference material.
Sir James Dewar was a major figure in British chemistry for around 40 years. He held the posts of Jacksonian Professor of Natural Philosophy at Cambridge (1875-1923) and Fullerian Professor of Chemistry at the Royal Institution (1877-1923) and is remembered principally for his efforts to liquefy hydrogen successfully in the field that would come to be known as cryogenics. His experiments in this field led him to develop the vacuum flask, now more commonly known as the thermos, and in 1898 he was the first person to successfully liquefy hydrogen. A man of many interests, he was also, with Frederick Abel, the inventor of explosive cordite, an achievement that involved him in a major legal battle with Alfred Nobel. Indeed, Dewar's career saw him involved in a number of public quarrels with fellow scientists; he was a fierce and sometimes unscrupulous defender of his rights and his claims to priority in a way that throws much light on the scientific spirit and practice of his day. This, the first scholarly biography of Dewar, seeks to resurrect and reinterpret a man who was a giant of his time, but is now sadly overlooked. In so doing, the book will shed much new light on the scientific culture of the late-nineteenth and early-twentieth centuries and the development of the field of chemistry in Britain.
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 contemporary scientific subjects. He, Davy, and Young were to become Britain s leading scientific practitioners in the first third of the nineteenth century, and their deaths within a six month time span were seen by many as the end of a glorious period of British supremacy in science. In contrast to his two more famous colleagues, Wollaston s life was not recorded for posterity in a contemporary biography, and his many remarkable scientific, commercial, instrumental, and institutional achievements have fallen into obscurity as a result. This biography is the first book-length study of Wollaston, his science, and the environment in which he thrived."
Painting with Fire shows how experiments with chemicals known to change visibly over the course of time transformed British pictorial arts of the long eighteenth century—and how they can alter our conceptions of photography today. As early as the 1670s, experimental philosophers at the Royal Society of London had studied the visual effects of dynamic combustibles. By the 1770s, chemical volatility became central to the ambitious paintings of Sir Joshua Reynolds, premier portraitist and first president of Britain’s Royal Academy of Arts. Valued by some critics for changing in time (and thus, for prompting intellectual reflection on the nature of time), Reynolds’s unstable chemistry also prompted new techniques of chemical replication among Matthew Boulton, James Watt, and other leading industrialists. In turn, those replicas of chemically decaying academic paintings were rediscovered in the mid-nineteenth century and claimed as origin points in the history of photography. Tracing the long arc of chemically produced and reproduced art from the 1670s through the 1860s, the book reconsiders early photography by situating it in relationship to Reynolds’s replicated paintings and the literal engines of British industry. By following the chemicals, Painting with Fire remaps familiar stories about academic painting and pictorial experiment amid the industrialization of chemical knowledge.
Throughout the nineteenth century, practitioners of science, writers of fiction and journalists wrote about electricity in ways that defied epistemological and disciplinary boundaries. Revealing electricity as a site for intense and imaginative Victorian speculation, Stella Pratt-Smith traces the synthesis of nineteenth-century electricity made possible by the powerful combination of science, literature and the popular imagination. With electricity resisting clear description, even by those such as Michael Faraday and James Clerk Maxwell who knew it best, Pratt-Smith argues that electricity was both metaphorically suggestive and open to imaginative speculation. Her book engages with Victorian scientific texts, popular and specialist periodicals and the work of leading midcentury novelists, including Charles Dickens, Charlotte Bronte, Emily Bronte, William Makepeace Thackeray and Wilkie Collins. Examining the work of William Harrison Ainsworth and Edward Bulwer-Lytton, Pratt-Smith explores how Victorian novelists attributed magical qualities to electricity, imbuing it with both the romance of the past and the thrill of the future. She concludes with a case study of Benjamin Lumley’s Another World, which presents an enticing fantasy of electricity’s potential based on contemporary developments. Ultimately, her book contends that writing and reading about electricity appropriated and expanded its imaginative scope, transformed its factual origins and applications and contravened the bounds of literary genres and disciplinary constraints.
Now largely forgotten, Henry Enfield Roscoe was one of the most prominent chemists and educational reformers in Victorian Britain. His contributions include transforming Owens College into Victoria University, now the University of Manchester, campaigning for the reform of technical education, serving as the Liberal MP for South Manchester, and cofounding the Lister Institute of Preventative Medicine. In this detailed biography, authors Morris and Reed provide a timely and original contribution to the history of nineteenth-century British science and its relation to education, industry, and government policy, highlighting Roscoe's significant legacy as one of the leading scientists of his generation.