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In Inventing Chemistry, historian John C. Powers turns his attention to Herman Boerhaave (1668–1738), a Dutch medical and chemical professor whose work reached a wide, educated audience and became the template for chemical knowledge in the eighteenth century. The primary focus of this study is Boerhaave’s educational philosophy, and Powers traces its development from Boerhaave’s early days as a student in Leiden through his publication of the Elementa chemiae in 1732. Powers reveals how Boerhaave restructured and reinterpreted various practices from diverse chemical traditions (including craft chemistry, Paracelsian medical chemistry, and alchemy), shaping them into a chemical course that conformed to the pedagogical and philosophical norms of Leiden University’s medical faculty. In doing so, Boerhaave gave his chemistry a coherent organizational structure and philosophical foundation and thus transformed an artisanal practice into an academic discipline. Inventing Chemistry is essential reading for historians of chemistry, medicine, and academic life.
Chemistry and chemical engineering have changed significantly in the last decade. They have broadened their scopeâ€"into biology, nanotechnology, materials science, computation, and advanced methods of process systems engineering and controlâ€"so much that the programs in most chemistry and chemical engineering departments now barely resemble the classical notion of chemistry. Beyond the Molecular Frontier brings together research, discovery, and invention across the entire spectrum of the chemical sciencesâ€"from fundamental, molecular-level chemistry to large-scale chemical processing technology. This reflects the way the field has evolved, the synergy at universities between research and education in chemistry and chemical engineering, and the way chemists and chemical engineers work together in industry. The astonishing developments in science and engineering during the 20th century have made it possible to dream of new goals that might previously have been considered unthinkable. This book identifies the key opportunities and challenges for the chemical sciences, from basic research to societal needs and from terrorism defense to environmental protection, and it looks at the ways in which chemists and chemical engineers can work together to contribute to an improved future.
This book explores the importance of bodily fluids to the development of medical knowledge in the eighteenth century. While the historiography has focused on the role of anatomy, this study shows that the chemical analyses of bodily fluids in the Dutch Republic radically altered perceptions of the body, propelling forwards a new system of medicine. It examines the new research methods and scientific instruments available at the turn of the eighteenth century that allowed for these developments, taken forward by Herman Boerhaave and his students. Each chapter focuses on a different bodily fluid – saliva, blood, urine, milk, sweat, semen – to investigate how doctors gained new insights into physiological processes through chemical experimentation on these bodily fluids. The book reveals how physicians moved from a humoral theory of medicine to new chemical and mechanical models for understanding the body in the early modern period. In doing so, it uncovers the lives and works of an important group of scientists which grew to become a European-wide community of physicians and chemists.
This is the first comprehensive history of the chemistry department at Imperial College London. Based on archival records, oral testimony, published papers, published and unpublished memoirs, the book tells the story of this world-famous department from its foundation as the Royal College of Chemistry in 1845 to the large department it had become by the year 2000.The book covers research, teaching, departmental governance, students and social life. It also highlights the extraordinary contributions made to the war effort in both the first and second world wars. From its first professors, A. Wilhelm Hofmann and Edward Frankland, the department has been home to many eminent chemists, including, in the later twentieth century, the Nobel laureates Derek Barton and Geoffrey Wilkinson. New information on these and many others is presented in a lively narrative that places both people and events in the larger historical contexts of chemistry, politics, culture and the economy. The book will interest not only those connected with Imperial College, but anyone interested in chemistry and its history, or in higher
During the seventeenth and eighteenth centuries, Europeans raised a number of questions about the nature of reality and found their answers to be different from those that had satisfied their forebears. They discounted tales of witches, trolls, magic, and miraculous transformations and instead began looking elsewhere to explain the world around them. In The Limits of Matter, Hjalmar Fors investigates how conceptions of matter changed during the Enlightenment and pins this important change in European culture to the formation of the modern discipline of chemistry. Fors reveals how, early in the eighteenth century, chemists began to view metals no longer as the ingredients for “chrysopoeia”—or gold making—but as elemental substances, or the basic building blocks of matter. At the center of this emerging idea, argues Fors, was the Bureau of Mines of the Swedish State, which saw the practical and profitable potential of these materials in the economies of mining and smelting. By studying the chemists at the Swedish Bureau of Mines and their networks, and integrating their practices into the wider European context, Fors illustrates how they and their successors played a significant role in the development of our modern notion of matter and made a significant contribution to the modern European view of reality.
A Cultural History of Chemistry in the Early Modern Age covers the period from 1500 to 1700, tracing chemical debates and practices within their cultural, social, and political contexts. This era in the history of chemistry was notable for natural philosophy, scientific discovery, and experimental method, and also as the high point of European alchemy - exemplified by the immensely popular writings of Paracelsus. Developments in the chemistry of metallurgy, medicine, distillation, and the applied arts encouraged attention to materials and techniques, linking theoretical speculation with practical know-how. Chemistry emerged as an academic discipline - supported by educational texts and based in classroom and laboratory instruction – and claimed a public place. The 6 volume set of the Cultural History of Chemistry presents the first comprehensive history from the Bronze Age to today, covering all forms and aspects of chemistry and its ever-changing social context. The themes covered in each volume are theory and concepts; practice and experiment; laboratories and technology; culture and science; society and environment; trade and industry; learning and institutions; art and representation. Bruce T. Moran is Professor of History and University Foundation Professor (emeritus) at the University of Nevada, Reno, USA. Volume 3 in the Cultural History of Chemistry set. General Editors: Peter J. T. Morris, University College London, UK, and Alan Rocke, Case Western Reserve University, USA.
Making Physicians displays the pedagogical practices that formed students into physicians, debunking longstanding myths by showing how much anatomy, sense experience, and materials mattered to Galenic medicine. Humanist book learning combined with hands-on training with medicines and exploring bodies, both living and dead.
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.