Antoine Lavoisier, the Next Crucial Year, Or The Sources of His Quantitative Method in Chemistry


Book Description

Through his development of quantitative experimental methods, the chemist Antoine Lavoisier (1743-1794) implemented a principle that many regard as the cornerstone of modern science: in every operation there is an equal quantity of material before and after the operation. The origin of Lavoisier's methods, however, has remained a missing piece in this remarkable episode of scientific history, perhaps because the talented young scientist himself was not prepared for the journey his discoveries would set before him. In this book, Frederic Holmes suggests that Lavoisier gradually came to understand the nature and power of his quantitative method during the year 1773, when he began to carry out a research program on the fixation and release of airs. Drawing upon Lavoisier's surviving laboratory notebooks, Holmes presents an engaging portrait of a scientist still seeking the way that would lead him to become the leader of one of the great upheavals in the history of science. Holmes follows Lavoisier day-by-day at work in his laboratory over a course of several months. The scientist's resourcefulness and imagination spring to life in this account, as does his propensity to make mistakes, which taught him as much as his successes. During the course of this odyssey, Lavoisier saw his early theory of combustion collapse under the weight of his own efforts to provide experimental evidence to support it. In compensation, he acquired a method and the hard-won experience on which he would later construct a more enduring theoretical structure. Originally published in 1997. The Princeton Legacy Library uses the latest print-on-demand technology to again make available previously out-of-print books from the distinguished backlist of Princeton University Press. These paperback editions preserve the original texts of these important books while presenting them in durable paperback editions. The goal of the Princeton Legacy Library is to vastly increase access to the rich scholarly heritage found in the thousands of books published by Princeton University Press since its founding in 1905.




Antoine Lavoisier: The Next Crucial Year


Book Description

Through his development of quantitative experimental methods, the chemist Antoine Lavoisier (1743-1794) implemented a principle that many regard as the cornerstone of modern science: in every operation there is an equal quantity of material before and after the operation. The origin of Lavoisier's methods, however, has remained a missing piece in this remarkable episode of scientific history, perhaps because the talented young scientist himself was not prepared for the journey his discoveries would set before him. In this book, Frederic Holmes suggests that Lavoisier gradually came to understand the nature and power of his quantitative method during the year 1773, when he began to carry out a research program on the fixation and release of airs. Drawing upon Lavoisier's surviving laboratory notebooks, Holmes presents an engaging portrait of a scientist still seeking the way that would lead him to become the leader of one of the great upheavals in the history of science. Holmes follows Lavoisier day-by-day at work in his laboratory over a course of several months. The scientist's resourcefulness and imagination spring to life in this account, as does his propensity to make mistakes, which taught him as much as his successes. During the course of this odyssey, Lavoisier saw his early theory of combustion collapse under the weight of his own efforts to provide experimental evidence to support it. In compensation, he acquired a method and the hard-won experience on which he would later construct a more enduring theoretical structure. Originally published in 1997. The Princeton Legacy Library uses the latest print-on-demand technology to again make available previously out-of-print books from the distinguished backlist of Princeton University Press. These editions preserve the original texts of these important books while presenting them in durable paperback and hardcover editions. The goal of the Princeton Legacy Library is to vastly increase access to the rich scholarly heritage found in the thousands of books published by Princeton University Press since its founding in 1905.




Matter and Method in the Long Chemical Revolution


Book Description

The seventeenth-century scientific revolution and the eighteenth-century chemical revolution are rarely considered together, either in general histories of science or in more specific surveys of early modern science or chemistry. This tendency arises from the long-held view that the rise of modern physics and the emergence of modern chemistry comprise two distinct and unconnected episodes in the history of science. Although chemistry was deeply transformed during and between both revolutions, the scientific revolution is traditionally associated with the physical and mathematical sciences whereas modern chemistry is seen as the exclusive product of the chemical revolution. This historiographical tension, between similarity in ’form’ and disparity in historical ’content’ of the two events, has tainted the way we understand the rise of modern chemistry as an integral part of the advent of modern science. Against this background, Matter and Method in the Long Chemical Revolution examines the role of and effects on chemistry of both revolutions in parallel, using chemistry during the chemical revolution to illuminate chemistry during the scientific revolution, and vice versa. Focusing on the crises and conflicts of early modern chemistry (and their retrospectively labeled ’losing’ parties), the author traces patterns of continuity in matter theory and experimental method from Boyle to Lavoisier, and reevaluates the disciplinary relationships between chemists, mechanists, and Newtonians in France, England, and Scotland. Adopting a unique approach to the study of the scientific and chemical revolutions, and to early modern chemical thought and practice in particular, the author challenges the standard revolution-centered history of early modern science, and reinterprets the rise of chemistry as an independent discipline in the long eighteenth century.




Lavoisier in the Year One: The Birth of a New Science in an Age of Revolution (Great Discoveries)


Book Description

"Fresh…solid…full of suspense and intrigue." —Publishers Weekly Antoine Lavoisier reinvented chemistry, overthrowing the long-established principles of alchemy and inventing an entirely new terminology, one still in use by chemists. Madison Smartt Bell’s enthralling narrative reads like a race to the finish line, as the very circumstances that enabled Lavoisier to secure his reputation as the father of modern chemistry—a considerable fortune and social connections with the likes of Benjamin Franklin—also caused his glory to be cut short by the French Revolution.




Alchemy Tried in the Fire


Book Description

Winner of the 2005 Pfizer Prize from the History of Science Society. What actually took place in the private laboratory of a mid-seventeenth century alchemist? How did he direct his quest after the secrets of Nature? What instruments and theoretical principles did he employ? Using, as their guide, the previously misunderstood interactions between Robert Boyle, widely known as "the father of chemistry," and George Starkey, an alchemist and the most prominent American scientific writer before Benjamin Franklin as their guide, Newman and Principe reveal the hitherto hidden laboratory operations of a famous alchemist and argue that many of the principles and practices characteristic of modern chemistry derive from alchemy. By analyzing Starkey's extraordinary laboratory notebooks, the authors show how this American "chymist" translated the wildly figurative writings of traditional alchemy into quantitative, carefully reasoned laboratory practice—and then encoded his own work in allegorical, secretive treatises under the name of Eirenaeus Philalethes. The intriguing "mystic" Joan Baptista Van Helmont—a favorite of Starkey, Boyle, and even of Lavoisier—emerges from this study as a surprisingly central figure in seventeenth-century "chymistry." A common emphasis on quantification, material production, and analysis/synthesis, the authors argue, illustrates a continuity of goals and practices from late medieval alchemy down to and beyond the Chemical Revolution. For anyone who wants to understand how alchemy was actually practiced during the Scientific Revolution and what it contributed to the development of modern chemistry, Alchemy Tried in the Fire will be a veritable philosopher's stone.




Lavoisier in the Year One


Book Description

Antoine Lavoisier-who lived at the zenith of the Enlightenment and died at the hands of the Revolution-was himself a revolutionary.




Chemical Research on Plant Growth


Book Description

Recherches Chimiques sur la Végétation was a seminal work in the development of the understanding of photosythesis and plant chemistry. The original publication, which was the first concise summation of the basics of plant nutrition, was a landmark in plant science. It was twice translated into German during the nineteenth century, but no English translation has been published. This translation will interest those in the plant, chemical, agricultural, and soil sciences, and the history of science, who find English more accessible than French or German and who wish to learn more about the early research on photosynthesis and plant science. A further note about the translation: This project is more than just a translation because it includes an extensive introduction as well as notes that provide explanations for archaic terminology and other background material. In the twentieth century, eminent photosynthesis researcher Eugene Rabinowitch described Recherches Chimiques sur la Végétation as the first modern book on plant nutrition. Historian of chemistry Henry Leicester called the book a classic, noting that the first important generalization about biochemistry in the nineteenth century came from it. Plant physiologist P. E. Pilet stated that the book laid the foundations of a new science, phytochemistry. Soil scientist E. Walter Russell attributed to de Saussure the quantitative experimental method, which more than anything else made modern agricultural chemistry possible. Chemist Leonard K. Nash stated that de Saussure brought the studies of plant nutrition begun by Priestley, Ingen-Housz, and Senebier close to completion, finishing the basic experimental work and providing a convincing theoretical interpretation of the field, and also opened up new vistas of experiment and thought. In the two centuries since Recherches Chimiques sur la Végétation was published, luminaries in various branches of science, including plant biology, chemistry, and soil science, have consistently praised it highly. In the nineteenth century, noted botanist Alphonse de Candolle and equally noted plant physiologist Julius von Sachs expressed great admiration for it. Although de Saussure’s ideas were forgotten for a time, famed chemist Justus von Liebig, who invented artificial fertilizer, rediscovered them in the 1840s and brought them to the attention of the agricultural community, stressing their importance for increasing crop yields.




Atoms and Alchemy


Book Description

Since the Enlightenment, alchemy has been viewed as a sort of antiscience, disparaged by many historians as a form of lunacy that impeded the development of rational chemistry. But in Atoms and Alchemy, William R. Newman—a historian widely credited for reviving recent interest in alchemy—exposes the speciousness of these views and challenges widely held beliefs about the origins of the Scientific Revolution. Tracing the alchemical roots of Robert Boyle’s famous mechanical philosophy, Newman shows that alchemy contributed to the mechanization of nature, a movement that lay at the very heart of scientific discovery. Boyle and his predecessors—figures like the mysterious medieval Geber or the Lutheran professor Daniel Sennert—provided convincing experimental proof that matter is made up of enduring particles at the microlevel. At the same time, Newman argues that alchemists created the operational criterion of an “atomic” element as the last point of analysis, thereby contributing a key feature to the development of later chemistry. Atomsand Alchemy thus provokes a refreshing debate about the origins of modern science and will be welcomed—and deliberated—by all who are interested in the development of scientific theory and practice.




100 Greatest Science Discoveries of All Time


Book Description

Brimming with fascinating and fun facts about 100 scientific breakthroughs, this collection presents the real stories behind the history of science, at the same time offering a panoramic overview of the history of science and an introduction to some of the most important scientists in history. Grades 6 and up. Throughout history, science has changed lives and dramatically altered the way in which the universe is perceived. Focusing on the 100 most significant scientific events of all time—from Archimedes' discovery of the two fundamental principles underlying physics and engineering (levers and buoyancy) in 260 B.C.E. to human anatomy, Jupiter's moons, electrons, black holes, the human genome, and more—storyteller Kendall Haven has created a ready reference for those seeking information on science discoveries.




Spaces of Enlightenment Science


Book Description

Spaces of Enlightenment Science explores the places, spaces, and exchanges where science of the Early Modern period got done, bringing together leading historians of science to examine the geographies of knowledge in the Enlightenment period.