The Elements
Autor Philip Ballen Limba Engleză Hardback – 8 sep 2021
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Specificații
ISBN-13: 9780500024539
ISBN-10: 0500024537
Pagini: 224
Ilustrații: 192 Illustrations, unspecified
Dimensiuni: 196 x 252 x 26 mm
Greutate: 1 kg
Editura: Thames & Hudson
ISBN-10: 0500024537
Pagini: 224
Ilustrații: 192 Illustrations, unspecified
Dimensiuni: 196 x 252 x 26 mm
Greutate: 1 kg
Editura: Thames & Hudson
Notă biografică
Philip Ball has written more than 20 books on scientific topics, including Elegant Solutions: Ten Beautiful Experiments in Chemistry (which was awarded the Dingle Prize for books by the British Society for the History of Science), Critical Mass (which won the Aventis Science Books award in 2005), and A Very Short Introduction to The Elements, one of the VSI series from Oxford University Press. Philip is a presenter of the science history series Science Stories on BBC Radio 4. He holds a BA in Chemistry from the University of Oxford and a PhD in Physics from the University of Bristol, and is a Fellow of the Royal Society of Chemistry and a board member of its magazine Chemistry World, in which he writes a regular column.
Recenzii
"One of the grandest rewards of the scientific perspective is that it allows us to view the familiar world in fresh and unfamiliar ways. . . . The Elements breaks physical reality down into its smallest cohesive parts, as have many other books about the periodic table. What is unusual here is the way this book builds the story back up. Ball, who originally trained as a chemist, plunges deep into the history of the elements, dividing it into eight eras, each defined by distinctive notions of what it means for a substance to be fundamental. . . . Today, the periodic table is still expanding, as researchers synthesize heavier and heavier atomic nuclei. But even the well-known elements remain in flux, changing with each shift in our scientific thinking. The book’s illustrations, meticulously researched and artfully presented, drive home the point. A gold-platinum mask, forged by an unknown pre-Columbian artist some 2,500 years ago, demonstrates an advanced understanding of alloys, but it stares out of the page with an almost alien visage."
"In this fascinating visual history of the elements, Ball spans over 3,000 years of scientific discovery from the classical era of Plato to the present day. Each element and story behind their discovery has been told in detail with the use of engaging images including scientific firsts in photography, as well as interesting artifacts and some beautiful historical drawings. More than this, the book is virtually a history of scientific discovery itself."
"Using some two hundred images, Ball describes how we discovered the building blocks of the universe—including some fake elements like phlogiston."
"This attractive, copiously illustrated book lays out the history of the discovery of the elements beginning with the insights of the classical Greeks and working forward to the most recent discoveries of superheavy elements. . . . Every page is filled with relevant quotes from literature and science as well as large, detailed illustrations. . . . The volume concludes with meticulous documentation of sources for quoted material and the usual list of further reading, illustration credits, and the like. . . . A very pleasant book to read and handle. . . . Recommended."
"Not only does the book deliver on its promise of making the elements seem like fully rounded characters, but it does so while retaining a critical eye for Eurocentric, anachronistic, and androcentric ways of laying out such tales of discovery. . . . The actual pictures in the book are as well designed as Ball’s overall ‘big picture.’ The tales of discovery are gorgeously punctuated with images as varied as wallpaper designed by William Morris and kohl from 1250–1200 BCE, not to mention various apparatuses, furnaces, and dusty chemistry kits. Crucially, the book’s visuality is not limited to its design but extends to the writing. There is, for instance, the account of the discovery of indium, involving a color-blind chemist facing up to the challenge of spectroscopy: its melting point is that at which melted sugar turns into toffee. Imaginaries like this render Ball’s account of the elements a joy to read. . . . It is difficult to put down Ball’s visual history of the discovery of the elements without feeling like you got to know the elements better and had fun in the process. The book should be useful and interesting not only to those just starting to learn about the chemical elements and history of chemistry but also to the specialist—both in terms of its content and in the way it sets an example for popularizing history of science within the academy and beyond."
“Seldom has this reviewer had the pleasure to comment on such a beautifully written and lavishly illustrated book. . . . Ball turns his attention back to his first love of chemistry and to the discovery of the chemical elements. . . . His work shows all the attributes of high-quality popular science writing, as it is accessible to the layperson while also succeeding in interesting readers possessing a technical knowledge of the subject matter. . . . I thoroughly recommend Ball’s new book.”
"Ball offers a written and visual account of elements that blends in a natural way scientific, historical, and philosophical considerations. He creates a rich exposition that explains in simple terms central scientific tenets around elements, while highlighting the historical context in which they were studied, and critically discussing philosophical issues pertaining to chemistry. All this is presented in an aesthetically beautiful way, resulting in a truly wonderful book. . . . The book is unique in showing that element discovery is tangled up not only with economic growth, technology, medicine, and the arts but also with power struggles, wars, colonization, and environmental exploitation. Ball’s book tells that history in an accessible, insightful, and fascinating way."
“Engagingly written, accessible, detail-packed, and beautifully illustrated. What is more, to a degree unusual in popular accounts of scientific discovery, The Elements is history-minded: foregrounding practical contexts, uncertainties, and perspectives behind the stories it tells.”
“Ball has once again produced a terrific book, one that presents a tremendous amount of the history of chemistry in a manner that is engagingly written, beautifully illustrated, and conscientious about avoiding the usual traps of popular science: triumphalism, a Eurocentric and male bias, and a reliance on just-so stories that are inadequately supported by the evidence. I cannot think of another popular history of chemistry I have so enjoyed reading.”
Extras
Among the many discoveries that humans have made about the world we live in, one of the most profound, as well as the most useful, is what it is made from. Every substance we can see and feel is composed of atoms—too small to see even with conventional light microscopes—of which there are just 90 or so varieties. What’s more, many of those varieties are extremely rare; the familiar world encompasses perhaps just twenty to thirty of them. These varieties are called the chemical elements, and they help massively in the task of simplifying our understanding of the world around us. There was no guarantee, before we knew of these elements, that all matter could be dissected and categorized into such a relatively small number of fundamental constituents—compare this, for example, to the profusion of species we find in the living world, where there are more than 300,000 known varieties (and probably more than that still unknown) of beetles alone. So the manageably limited list of chemical elements is something to be grateful for.
All the same, it’s a dauntingly long list for new students of chemistry. They might have already heard of elements like carbon and oxygen, but scandium? Praesodymium? Even pronouncing the names of some of these elements can be a challenge, let alone remembering anything about them or finding the motivation to do so.
That’s where history might help. The elements were discovered only very gradually over time—from about 1730, at a surprisingly steady rate of about one every two or three years, with occasional bursts or hiatuses. This happened through no concerted program of seeking (at least not until the past several decades, when any newly discovered elements have had to be deliberately human-made). It was a haphazard business: scientists and technologists might find a previously unknown element in an obscure mineral, say, or by splitting sunlight into a spectrum to seek a telltale gap where some new element has stripped a color from it, or by liquefying and distilling air to find tiny quantities of rare gases. These tales of discovery are like biographies, and they can make the elements seem less like a random collection of obscure nobodies and more like characters in the long and continuing saga of how we have tried to comprehend and manipulate our surroundings. To chemists, they genuinely come to acquire personalities: helpful or recalcitrant, intriguing or dull, friendly or hazardous. That chemists regularly conduct polls of their “favorite elements” can seem unutterably nerdy—until you get to know the elements yourself, in which case you will almost certainly find that you have developed preferences and aversions of your own.
Some elements have proved immensely useful: as crucial ingredients in drugs or other medical agents, for example, or for making new materials that are harder, stronger, shinier, better conductors of electricity, and so on. Some have brightly colored compounds (combinations with other elements) that are valuable as pigments and dyes. Some are sources of energy, or essential nutrients for health, or refrigerants that can keep things colder than deep space. Their properties and uses have even elevated a few elements to privileged inclusion in the cultural lexicon: opportunities are golden, clouds have silver linings, suggestions go down like lead balloons, opponents are crushed with an iron fist, provocateurs are denied the oxygen of publicity. We might speak of the sodium glare of streetlights, of hydrogen bombs, of nickel-and-dime stores, magnesium flares, with little if any understanding of why those particular elements are being invoked. The very notion of an “element” itself connotes a fundamental principle beyond chemistry, for we speak of the elements of law, of mathematics (the topic of the ancient Greek thinker Euclid’s treatise The Elements), of language, of cookery.
All this implies that charting the history of the discovery of the chemical elements is more than an account of the development of chemistry as a science. It also offers us a view of how we have come to understand the natural world, including our own constitution. Furthermore, it shows how this knowledge has accompanied the evolution of our technologies and crafts—and “accompany” is the right word to use, because this narrative challenges the common but inaccurate view that science always moves from discovery to application. Often it is the reverse: practical concerns (such as mining or manufacturing) generate questions and challenges that lead to fresh discoveries. We can see too how scientific discovery is not some impersonal and inexorable process, but depends instead on the motivations, capabilities, and sometimes the idiosyncrasies of individual people: it requires determination, imagination, and ambition as well as insight and—never underestimate this—a substantial dash of good luck.
It’s an unavoidable fact that histories of this kind must dwell, especially in the past several centuries, to a degree that we now rightly find uncomfortable, on the exploits and achievements of men of European heritage. Not only was it very difficult until recent times for women to gain entry into scientific institutions, but even those few who did often faced intense discrimination and prejudice. Marie Curie, for example, who did most of the work in finding the elements radium and polonium at the end of the nineteenth century, was nearly overlooked when the work was rewarded by the 1903 Nobel Prize for Physics. Initially, the award was going to acknowledge only her husband and collaborator Pierre, before, forewarned, he objected. Similarly, Marie-Anne Paulze Lavoisier’s contributions to the work of her husband, the eminent eighteenth-century French chemist Antoine Lavoisier, were long considered little more than wifely duties rather than those of a scientific collaborator. Even as late as the 1950s, the American nuclear chemist Darleane Hoffman, who made vital contributions to the discoveries of new, heavy radioactive elements, was told when she arrived at Los Alamos National Laboratory to lead a new team that there must be some mistake because “We don’t hire women in that division.”
Why, meanwhile, people of color feature rather little in this story is a question fraught with the entire history of Western global dominance and exploitation since early modern times, as well as the prejudices and systematic biases that still lead to their under-representation in the sciences today. It isn’t clear for how much longer the story of element discovery will or, for that matter, can continue—but the rise of scientific excellence in Asia, at least, might lead us to expect as well as to hope that, if it does, then it will feature significantly more cultural richness and diversity.
All the same, it’s a dauntingly long list for new students of chemistry. They might have already heard of elements like carbon and oxygen, but scandium? Praesodymium? Even pronouncing the names of some of these elements can be a challenge, let alone remembering anything about them or finding the motivation to do so.
That’s where history might help. The elements were discovered only very gradually over time—from about 1730, at a surprisingly steady rate of about one every two or three years, with occasional bursts or hiatuses. This happened through no concerted program of seeking (at least not until the past several decades, when any newly discovered elements have had to be deliberately human-made). It was a haphazard business: scientists and technologists might find a previously unknown element in an obscure mineral, say, or by splitting sunlight into a spectrum to seek a telltale gap where some new element has stripped a color from it, or by liquefying and distilling air to find tiny quantities of rare gases. These tales of discovery are like biographies, and they can make the elements seem less like a random collection of obscure nobodies and more like characters in the long and continuing saga of how we have tried to comprehend and manipulate our surroundings. To chemists, they genuinely come to acquire personalities: helpful or recalcitrant, intriguing or dull, friendly or hazardous. That chemists regularly conduct polls of their “favorite elements” can seem unutterably nerdy—until you get to know the elements yourself, in which case you will almost certainly find that you have developed preferences and aversions of your own.
Some elements have proved immensely useful: as crucial ingredients in drugs or other medical agents, for example, or for making new materials that are harder, stronger, shinier, better conductors of electricity, and so on. Some have brightly colored compounds (combinations with other elements) that are valuable as pigments and dyes. Some are sources of energy, or essential nutrients for health, or refrigerants that can keep things colder than deep space. Their properties and uses have even elevated a few elements to privileged inclusion in the cultural lexicon: opportunities are golden, clouds have silver linings, suggestions go down like lead balloons, opponents are crushed with an iron fist, provocateurs are denied the oxygen of publicity. We might speak of the sodium glare of streetlights, of hydrogen bombs, of nickel-and-dime stores, magnesium flares, with little if any understanding of why those particular elements are being invoked. The very notion of an “element” itself connotes a fundamental principle beyond chemistry, for we speak of the elements of law, of mathematics (the topic of the ancient Greek thinker Euclid’s treatise The Elements), of language, of cookery.
All this implies that charting the history of the discovery of the chemical elements is more than an account of the development of chemistry as a science. It also offers us a view of how we have come to understand the natural world, including our own constitution. Furthermore, it shows how this knowledge has accompanied the evolution of our technologies and crafts—and “accompany” is the right word to use, because this narrative challenges the common but inaccurate view that science always moves from discovery to application. Often it is the reverse: practical concerns (such as mining or manufacturing) generate questions and challenges that lead to fresh discoveries. We can see too how scientific discovery is not some impersonal and inexorable process, but depends instead on the motivations, capabilities, and sometimes the idiosyncrasies of individual people: it requires determination, imagination, and ambition as well as insight and—never underestimate this—a substantial dash of good luck.
It’s an unavoidable fact that histories of this kind must dwell, especially in the past several centuries, to a degree that we now rightly find uncomfortable, on the exploits and achievements of men of European heritage. Not only was it very difficult until recent times for women to gain entry into scientific institutions, but even those few who did often faced intense discrimination and prejudice. Marie Curie, for example, who did most of the work in finding the elements radium and polonium at the end of the nineteenth century, was nearly overlooked when the work was rewarded by the 1903 Nobel Prize for Physics. Initially, the award was going to acknowledge only her husband and collaborator Pierre, before, forewarned, he objected. Similarly, Marie-Anne Paulze Lavoisier’s contributions to the work of her husband, the eminent eighteenth-century French chemist Antoine Lavoisier, were long considered little more than wifely duties rather than those of a scientific collaborator. Even as late as the 1950s, the American nuclear chemist Darleane Hoffman, who made vital contributions to the discoveries of new, heavy radioactive elements, was told when she arrived at Los Alamos National Laboratory to lead a new team that there must be some mistake because “We don’t hire women in that division.”
Why, meanwhile, people of color feature rather little in this story is a question fraught with the entire history of Western global dominance and exploitation since early modern times, as well as the prejudices and systematic biases that still lead to their under-representation in the sciences today. It isn’t clear for how much longer the story of element discovery will or, for that matter, can continue—but the rise of scientific excellence in Asia, at least, might lead us to expect as well as to hope that, if it does, then it will feature significantly more cultural richness and diversity.
Cuprins
Introduction
The Periodic Table
Chapter 1. The Classical Elements
Chapter 2. The Antique Metals
Chapter 3. Alchemical Elements
Interlude: What Exactly Is an Element?
Chapter 4. The New Metals
Chapter 5. Chemistry’s Golden Age
Interlude: John Dalton’s Atoms
Chapter 6. Electrical Discoveries
Interlude: The Periodic Table
Chapter 7. The Radiant Age
Chapter 8. The Nuclear Age
Sources for Quotes
Further Reading
Index
Picture Credits
The Periodic Table
Chapter 1. The Classical Elements
Chapter 2. The Antique Metals
Chapter 3. Alchemical Elements
Interlude: What Exactly Is an Element?
Chapter 4. The New Metals
Chapter 5. Chemistry’s Golden Age
Interlude: John Dalton’s Atoms
Chapter 6. Electrical Discoveries
Interlude: The Periodic Table
Chapter 7. The Radiant Age
Chapter 8. The Nuclear Age
Sources for Quotes
Further Reading
Index
Picture Credits