This is the absorbing account of one of the twentieth century’s most revolutionary discoveries — our first encounter with an essential mystery of the universe. Told by an active participant in this discovery, it is the saga of the search for quarks, the elementary particles lurking within the protons and neutrons of atomic nuclei, which constitute the fundamental basis of matter. Michael Riordan, physicist and author, was present at the key moments in this story. He brings to life the personalities, triumphs and failures of this true-life scientific detective story, vividly portraying the soaring ambitions and clashing egos of modern physicists at work, vying for the coveted Nobel Prize. The Hunting of the Quark gives readers an insider’s perspective on how frontier science actually occurs — the great leaps of imagination, the blind alleys followed, and the final resolution of the mysteries that had to be overcome on the road to unity. Like James Watson’s famous accountThe Double Helix, it has the immediacy and excitement of being on the trail of a monumental discovery — leading to a striking new scientific paradigm, the Standard Model of particle physics. “Many books on the 20th-century revolution in particle physics focus on the startling new notions introduced. Not as much attention is paid to those who dirtied their hands, nursing crotchety accelerator instruments, in order to prove the conjectures. Mr. Riordan, a physicist affiliated with the Stanford Linear Accelerator Center, presents an authoritative account of this less-told tale. A veteran quark-stalker himself, he deftly combines his technical expertise with a journalistic flair, personally acquainting us with many of the men and women who joined in the hunt... Mr. Riordan enables us to behold exactly how physicists work and the tortuous paths that experimentalists must travel to gain just a scrap of insight into the puzzling laws of nature.” — Marcia Bartusiak, The New York Times “A great book that I couldn’t put down even though I knew the plot.” — Sheldon Glashow, Eugene Higgins Professor of Physics, Emeritus, Harvard University, Nobel prize in physics (1979) “Machines two miles long, pieces of matter elusive as lost souls, the likes of Richard Feynman ‘snooping around,’ reputations made and lost on the contumacious front lines of science — what a wonderful mix for a book. Particle physics has seemed arcane, the quark business most of all. Michael Riordan, who lives the story he tells, makes it lively, literate and accessible.” — Richard Rhodes, author of The Making of the Atomic Bomb “Mr. Riordan... understands the physics, but he also has an eye for the human comedy associated with the work. The result is a fine book on elementary particle physics.” — Jeremy Bernstein, The New Yorker “Riordan was an active participant in the search for the enigmatic quark, and his story reflects the excitement, passion and revelation of peeking into nature’s most elusive realm.” — Rudy Rucker, San Francisco Chronicle “An enjoyable book with enough good explanations and clear discussions to make it well worth reading both for the expert in modern high-energy physics and for the general reader.” — Alexander Firestone, Physics Today “A physicist with first-hand experience chasing quarks at the Stanford Linear Accelerator Center (SLAC) relates the high points of the search for those elusive subatomic particles... Riordan builds a suspenseful tale around the neck-and-neck race between MIT/Brookhaven (Sam Ting) and Stanford (Burton Richter) in discovering the J/psi particle... Riordan’s epilogue is eloquent... Readers will... turn to Riordan for a close-in view and astute commentary on a pivotal period in 20th-century physics.” —Kirkus

The twentieth century was defined by physics. From the minds of the world's leading physicists there flowed a river of ideas that would transport mankind to the pinnacle of wonderment and to the very depths of human despair. This was a century that began with the certainties of absolute knowledge and ended with the knowledge of absolute uncertainty. It was a century in which physicists developed weapons with the capacity to destroy our reality, whilst at the same time denying us the possibility that we can ever properly comprehend it. Almost everything we think we know about the nature of our world comes from one theory of physics. This theory was discovered and refined in the first thirty years of the twentieth century and went on to become quite simply the most successful theory of physics ever devised. Its concepts underpin much of the twenty-first century technology that we have learned to take for granted. But its success has come at a price, for it has at the same time completely undermined our ability to make sense of the world at the level of its most fundamental constituents. Rejecting the fundamental elements of uncertainty and chance implied by quantum theory, Albert Einstein once famously declared that 'God does not play dice'. Niels Bohr claimed that anybody who is not shocked by the theory has not understood it. The charismatic American physicist Richard Feynman went further: he claimed that nobody understands it. This is quantum theory, and this book tells its story. Jim Baggott presents a celebration of this wonderful yet wholly disconcerting theory, with a history told in forty episodes — significant moments of truth or turning points in the theory's development. From its birth in the porcelain furnaces used to study black body radiation in 1900, to the promise of stimulating new quantum phenomena to be revealed by CERN's Large Hadron Collider over a hundred years later, this is the extraordinary story of the quantum world. Oxford Landmark Science books are 'must-read' classics of modern science writing which have crystallized big ideas, and shaped the way we think.

From acclaimed science author Jim Baggot, a lively, provocative, and “intellectually gratifying” critique of modern theoretical physics (The Economist). In this stunning new volume, Jim Baggott argues that there is no observational or experimental evidence for many of the ideas of modern theoretical physics: super-symmetric particles, superstrings, the multiverse, the holographic principle, or the anthropic cosmological principle. These theories are not only untrue, it is not even science. It is fairy-tale physics: fantastical, bizarre and often outrageous, perhaps even confidence-trickery. This book provides a much-needed antidote. Informed, comprehensive, and balanced, it offers lay readers the latest ideas about the nature of physical reality while clearly distinguishing between fact and fantasy. With its engaging portraits of many central figures of modern physics, including Paul Davies, John Barrow, Brian Greene, Stephen Hawking, and Leonard Susskind, it promises to be essential reading for all readers interested in what we know and don''''t know about the nature of the universe and reality itself.

The first up-to-date book written for the popular enthusiast market which describes the development of modern particle physics and its importance in improving our understanding of the origin and evolution of the Universe.

The scope of the book is to give an overview of the history of astroparticle physics, starting with the discovery of cosmic rays (Victor Hess, 1912) and its background (X-ray, radioactivity). The book focusses on the ways in which physics changes in the course of this history. The following changes run parallel, overlap, and/or interact: - Discovery of effects like X-rays, radioactivity, cosmic rays, new particles but also progress through non-discoveries (monopoles) etc. - The change of the description of nature in physics, as consequence of new theoretical questions at the beginning of the 20th century, giving rise to quantum physics, relativity, etc. - The change of experimental methods, cooperations, disciplinary divisions. With regard to the latter change, a main topic of the book is to make the specific multi-diciplinary features of astroparticle physics clear.

This volume assembles cutting-edge scholarship on scientific understanding, scientific representation, and their delicate interplay. Featuring several articles in an engaging ‘critical conversation’ format, the volume integrates discussions about understanding and representation with perennial issues in the philosophy of science, including the nature of scientific knowledge, idealizations, scientific realism, scientific inference, and scientific progress. In the philosophy of science, questions of scientific understanding and scientific representation have only recently been put in dialogue with each other. The chapters advance these discussions from a variety of fresh perspectives. They range from case studies in physics, chemistry, and neuroscience to the representational challenges of machine learning models; from special forms of representation such as maps and topological models to the relation between understanding and explanation; and from the role of idealized representations to the role of representation and understanding in scientific progress. Scientific Understanding and Representation will appeal to scholars and advanced students working in philosophy of science, philosophy of physics, philosophy of mathematics, and epistemology.

The International Conference on the History of Original Ideas and Basic Discoveries, held at the "Ettore Majorana" Centre for Scientific Culture in Erice, Sicily, July 27-August 4, 1994, brought together sixty of the leading scientists including many Nobel Laureates in high energy physics, principal contributors in other fields of physics such as high Tc superconductivity, particle accelerators and detector instrumentation, and thirty-six talented younger physicists selected from candidates throughout the world. The scientific program, including 49 lectures and a discussion session on the "Status and Future Directions in High Energy Physics" was inspired by the conference theme: The key experimental discoveries and theoretical breakthroughs of the last 50 years, in particle physics and related fields, have led us to a powerful description of matter in terms of three quark and three lepton families and four fundamental interactions. The most recent generation of experiments at e+e- and proton-proton colliders, and corresponding advances in theoretical calculations, have given us remarkably precise determinations of the basic parameters of the electroweak and strong interactions. These developments, while showing the striking internal consistency of the Standard Model, have also sharpened our view of the many unanswered questions which remain for the next generation: the origin and pattern of particle masses and families, the unification of the interactions including gravity, and the relation between the laws of physics and the initial conditions of the universe.