Reputed to have performed miraculous feats in New England—restoring the hair and teeth to an aged lady, bringing a withered peach tree to fruit—Eirenaeus Philalethes was also rumored to be an adept possessor of the alchemical philosophers’ stone. That the man was merely a mythical creation didn’t diminish his reputation a whit—his writings were spectacularly successful, read by Leibniz, esteemed by Newton and Boyle, voraciously consumed by countless readers. Gehennical Fire is the story of the man behind the myth, George Starkey.
Though virtually unknown today and little noted in history, Starkey was America’s most widely read and celebrated scientist before Benjamin Franklin. Born in Bermuda, he received his A.B. from Harvard in 1646 and four years later emigrated to London, where he quickly gained prominence as a “chymist.” Thanks in large part to the scholarly detective work of William Newman, we now know that this is only a small part of an extraordinary story, that in fact George Starkey led two lives. Not content simply to publish his alchemical works under the name Eirenaeus Philalethes, “A Peaceful Lover of Truth,” Starkey spread elaborate tales about his alter ego, in effect giving him a life of his own.
The demonstrations capture interest, teach, inform, fascinate, amaze, and perhaps, most importantly, involve students in chemistry. Nowhere else will you find books that answer, "How come it happens? . . . Is it safe? . . . What do I do with all the stuff when the demo is over?"
Shakhashiri and his collaborators offer 282 chemical demonstrations arranged in 11 chapters. Each demonstration includes seven sections: a brief summary, a materials list, a step-by-step account of procedures to be used, an explanation of the hazards involved, information on how to store or dispose of the chemicals used, a discussion of the phenomena displayed and principles illustrated by the demonstration, and a list of references.
Color and light are the focus of this long-awaited fifth volume in the Chemical Demonstrations series, which describes demonstrations that effectively communicate science to both students and general audiences. Using full color illustrations, the book provides meticulous instructions for safely demonstrating colorful phenomena and illustrating scientific principles. A rich introductory section explores the science of color and light, outlines the chemical processes of vision, and explains what happens when visual information enters the human eye and is perceived by the brain. With more than fifty demonstrations and multiple procedures included, this volume offers abundant opportunities to arouse and sustain interest in science for both classroom and public presentations.
Each demonstration includes:
• a brief description of the demonstration
• a materials list
• a step-by-step account of procedures to be used
• an explanation of the potential hazards involved
• information on safely storing and disposing the chemicals used
• a full discussion of the phenomena displayed and principles illustrated
• a list of references.
Created by acclaimed chemists and science educators Bassam Shakhashiri and his collaborators Rodney Schreiner and Jerry Bell, these demonstrations make an impressive addition to the earlier volumes, which have been lauded for guiding teachers and scientists in effectively communicating science. Like all volumes in the series, Volume 5 communicates chemistry using pedagogical knowledge to enhance the effectiveness of demonstrations to all audiences.
Seduced by simplicity, physicists find themselves endlessly fascinated by hydrogen, the simplest of atoms. Hydrogen has shocked, it has surprised, it has embarrassed, it has humbled--and again and again it has guided physicists to the edge of new vistas where the promise of basic understanding and momentous insights beckoned. The allure of hydrogen, crucial to life and critical to scientific discovery, is at the center of this book, which tells a story that begins with the big bang and continues to unfold today.
In this biography of hydrogen, John Rigden shows how this singular atom, the most abundant in the universe, has helped unify our understanding of the material world from the smallest scale, the elementary particles, to the largest, the universe itself. It is a tale of startling discoveries and dazzling practical benefits spanning more than one hundred years--from the first attempt to identify the basic building block of atoms in the mid-nineteenth century to the discovery of the Bose-Einstein condensate only a few years ago. With Rigden as an expert and engaging guide, we see how hydrogen captured the imagination of many great scientists--such as Heisenberg, Pauli, Schrödinger, Dirac, and Rabi--and how their theories and experiments with this simple atom led to such complex technical innovations as magnetic resonance imaging, the maser clock, and global positioning systems. Along the way, we witness the transformation of science from an endeavor of inspired individuals to a monumental enterprise often requiring the cooperation of hundreds of scientists around the world.
Still, any biography of hydrogen has to end with a question: What new surprises await us?
Nineteenth-century chemists were faced with a particular problem: how to depict the atoms and molecules that are beyond the direct reach of our bodily senses. In visualizing this microworld, these scientists were the first to move beyond high-level philosophical speculations regarding the unseen. In Image and Reality, Alan Rocke focuses on the community of organic chemists in Germany to provide the basis for a fuller understanding of the nature of scientific creativity.
Arguing that visual mental images regularly assisted many of these scientists in thinking through old problems and new possibilities, Rocke uses a variety of sources, including private correspondence, diagrams and illustrations, scientific papers, and public statements, to investigate their ability to not only imagine the invisibly tiny atoms and molecules upon which they operated daily, but to build detailed and empirically based pictures of how all of the atoms in complicated molecules were interconnected. These portrayals of “chemical structures,” both as mental images and as paper tools, gradually became an accepted part of science during these years and are now regarded as one of the central defining features of chemistry. In telling this fascinating story in a manner accessible to the lay reader, Rocke also suggests that imagistic thinking is often at the heart of creative thinking in all fields.
Image and Reality is the first book in the Synthesis series, a series in the history of chemistry, broadly construed, edited by Angela N. H. Creager, John E. Lesch, Stuart W. Leslie, Lawrence M. Principe, Alan Rocke, E.C. Spary, and Audra J. Wolfe, in partnership with the Chemical Heritage Foundation.
A fascinating natural history of an incredibly curious substance.
“Preternaturally hardened whale dung” is not the first image that comes to mind when we think of perfume, otherwise a symbol of glamour and allure. But the key ingredient that makes the sophisticated scent linger on the skin is precisely this bizarre digestive by-product—ambergris. Despite being one of the world’s most expensive substances (its value is nearly that of gold and has at times in history been triple it), ambergris is also one of the world’s least known. But with this unusual and highly alluring book, Christopher Kemp promises to change that by uncovering the unique history of ambergris.
A rare secretion produced only by sperm whales, which have a fondness for squid but an inability to digest their beaks, ambergris is expelled at sea and floats on ocean currents for years, slowly transforming, before it sometimes washes ashore looking like a nondescript waxy pebble. It can appear almost anywhere but is found so rarely, it might as well appear nowhere. Kemp’s journey begins with an encounter on a New Zealand beach with a giant lump of faux ambergris—determined after much excitement to nothing more exotic than lard—that inspires a comprehensive quest to seek out ambergris and its story. He takes us from the wild, rocky New Zealand coastline to Stewart Island, a remote, windswept island in the southern seas, to Boston and Cape Cod, and back again. Along the way, he tracks down the secretive collectors and traders who populate the clandestine modern-day ambergris trade.
Floating Gold is an entertaining and lively history that covers not only these precious gray lumps and those who covet them, but presents a highly informative account of the natural history of whales, squid, ocean ecology, and even a history of the perfume industry. Kemp’s obsessive curiosity is infectious, and eager readers will feel as though they have stumbled upon a precious bounty of this intriguing substance.
An eminent pioneer of modern protein chemistry looks back on six decades in biochemical research and education to advance stimulating thoughts about science—how it is practiced, how it is explained, and how its history is written. Taking the title of his book from Robert Boyle’s classic, The Sceptical Chymist (1661), and Joseph Needham’s The Sceptical Biologist (1929), Joseph Fruton brings his own skeptical vision to bear on how chemistry and biology interact to describe living systems.
Scientists, philosophers, historians, and sociologists will seize upon the questions Fruton raises: What is the nature of the tension between the chemical and the biological sciences? What are the roots and future direction of molecular biology? What is the proper place of expert scientists in the historiography of science? How does the “scientific method” really work in practice? These and many other topics are fair game for this author’s wise critiques. In a stimulating final chapter, Fruton analyzes the evolution of key terms and symbols—the conceptual underpinnings used in the biochemical literature.
This volume brings together two previously unpublished works by the late George Scatchard. One of the most eminent physical chemists of this century, Scatchard, in collaboration with Edwin Cohn, had enormous influence on the development of protein chemistry. The “Scatchard Plot,” a device for evaluating the interaction of proteins with smaller molecules, is today a ubiquitous feature of articles on biochemistry, immunology, and endocrinology.
These two monographs concern the laws of thermodynamics and the Oebye-Huckel theory as they are applied to the physical chemistry of inorganic and organic systems in solution. A unique feature of both works is their detailed extension of thermodynamic principles to the interactions of dissolved proteins with each other and with small molecules. They represent one of the most important links between the classical physical chemistry of the first four decades of this century and the contemporary science of protein chemistry.
Known previously only to a limited audience of Scatchard's students and colleagues, these remarkable treatises deserve much wider circulation today. Succinct, comprehensive, and systematic, they will stand as useful guides to one of the central sciences of our time.
After explaining the greenhouse effect, Pilkey, writing with son Keith, turns to the damage it is causing: sea level rise, ocean acidification, glacier and sea ice melting, changing habitats, desertification, and the threats to animals, humans, coral reefs, marshes, and mangroves. These explanations are accompanied by Mary Edna Fraser’s stunning batiks depicting the large-scale arenas in which climate change plays out.
The Pilkeys directly confront and rebut arguments typically advanced by global change deniers. Particularly valuable are their discussions of “Climategate,” a manufactured scandal that undermined respect for the scientific community, and the denial campaigns by the fossil fuel industry, which they compare to the tactics used by the tobacco companies a generation ago to obfuscate findings on the harm caused by cigarettes.
Not quite a history of geology, Thinking about the Earth is a history of the geological tradition of Western science. Beginning with a discussion of "organic" views of the earth in ancient cultures, David Oldroyd traverses such topics as "mechanical" and "historicist" views of the earth, map-work, chemical analyses of rocks and minerals, geomorphology, experimental petrology, seismology, theories of mountain building, and geochemistry. He brings us back to the idea that the earth may, in a sense, be regarded as a living entity, or at least that life is an essential feature of its behavior.
Oldroyd offers a broad-brush contribution to the history of ideas and theories about the earth, providing a general synthesis of what science-historians have written about the history of the earth sciences. He shows us that ideas about the earth have been changing constantly since the beginnings of geological science in the seventeenth and eighteenth centuries, and indeed that ideas changed much more rapidly after the establishment of this science than in preceding centuries.
Thinking about the Earth does not assume previous knowledge of earth science. What it does require is an openness to the notion that an understanding of what geologists have to tell us today about the earth can be achieved by examining the evolving history of ideas in geology. This book will be of considerable interest to historians of science, historians of ideas, geologists, students of earth science, and general readers as well.
Ralph J. Roberts is not a household name in Nevada, but it should be—it was he who discovered the Carlin Belt gold deposits that created a major mining boom in the state in the last four decades of the twentieth century. But this discovery was only one episode of his remarkably eventful life. This colorful and personal account of the author's search for his passion—gold—is a story as adventurous as that of any fictional character.
Henry Darwin Rogers was one of the first professional geologists in the United States. He directed two of the earliest state geological surveys--New Jersey and Pennsylvania--in the mid-1830s. His major interest was Pennsylvania, with its Appalachian Mountains, which Rogers saw as great folds of sedimentary rock. He belived that an interpretation of these folds would lead to an understanding of the dynamic processes that had shaped the earth. From Rogers' efforts to explain these Pennsylvania folds came the first uniquely American theory of mountain elevation, a theory that Rogers personally considered his most significant achievement.
READERS
Browse our collection.
PUBLISHERS
See BiblioVault's publisher services.
STUDENT SERVICES
Files for college accessibility offices.
UChicago Accessibility Resources
home | accessibility | search | about | contact us
BiblioVault ® 2001 - 2024
The University of Chicago Press