Faraday, Maxwell, and the electromagnetic field How two men revolutionized physics

Nancy Forbes

Book - 2014

Saved in:

2nd Floor Show me where

537/Forbes
1 / 1 copies available
Location Call Number   Status
2nd Floor 537/Forbes Checked In
Subjects
Published
Amherst, New York : Prometheus Books 2014.
Language
English
Main Author
Nancy Forbes (author)
Other Authors
Basil Mahon (author)
Physical Description
320 pages : illustrations, portraits ; 24 cm
Bibliography
Includes bibliographical references and index.
ISBN
9781616149420
  • Acknowledgments
  • Chronology: Principal Events in the Story of the Electromagnetic Field
  • Introduction
  • 1. The Apprentice: 1791-1813
  • 2. Chemistry: 1813-1820
  • 3. History: 1600-1820
  • 4. A Circular Force: 1820-1831
  • 5. Induction: 1831-1840
  • 6. A Shadow of a Speculation: 1840-1857
  • 7. Faraday's Last Years: 1857-1867
  • 8. What's the Go o' That? 1831-1850
  • 9. Society and Drill: 1850-1854
  • 10. An Imaginary Fluid: 1854-1856
  • 11. No Jokes Are Understood Here: 1856-1860
  • 12. The Speed of Light: 1860-1863
  • 13. Great Guns: 1863-1865
  • 14. Country Life: 1865-1871
  • 15. The Cavendish:-1871-1879
  • 16. The Maxwellians: 1850-1890
  • 17. A New Epoch: 1890 Onward
  • Notes
  • Bibliography
  • Index
Review by Choice Review

The physics of the previous several centuries were mostly dominated by the idea that forces were transmitted instantaneously through a passive "space" to objects at some distance: action at a distance. Space was a fixed and empty stage on which the actors (forces) carried out their mission. The transformative notions of "field" and "space" that were developed during the 19th century, chiefly by Faraday and Maxwell, to help understand the ideas of electrical and magnetic properties have served as the umbrella under which much of 20th- and 21st-century physics is understood, i.e., quantum fields, elementary particle properties, and general relativity. For example, in understanding the evolution of the universe, space and time have emerged as active players participating in a fundamental way: the basic insight of modern cosmology. Here, science writers Forbes and Mahon beautifully execute a careful, detailed treatment of the 19th-century experiments and the reasoning behind them. In particular, Faraday emerges as a brilliant, inventive scientist, despite possessing little mathematical skill. Maxwell, charming and socially adept, appears to have found a way of integrating a host of seemingly unconnected ideas into four compact equations with enormous predictive power, a model for future theories. A wonderfully readable and informative book. --Kenneth L. Schick, Union College (NY)

Copyright American Library Association, used with permission.
Review by Publisher's Weekly Review

Science writers Forbes (Imitation of Life) and Mahon (The Man Who Changed Everything) explore the lives of ground-breaking physicists Michael Faraday and James Clerk Maxwell in this work that blends science history and lively biography. The authors describe how Faraday, a blacksmith's son, abandoned a promising career as a bookbinder in 1813 to study the young science of electricity. Faraday's attention to detail and skill as a "compulsive experimenter" led to the first electric motor, the first generator, and the idea that electricity and magnetism travel as waves, like sound and light. His work supported the concept of fields, but his lack of mathematical ability meant few took him seriously. Then Maxwell, a young professor from Marischal College in Aberdeen, Scotland, developed the math to back up Faraday's ideas. A prodigy with a "quicksilver mind" prone to expressing his feelings through verse, Maxwell was fascinated with Faraday's fields. Through Maxwell, these fields became a means of storing electromagnetic energy and transmitting forces to cause magnetic attraction and repulsion. Accessible writing and a feel for character make this an interesting look at two scientists whose work defined an era and set the course for modern physics. (Mar.) (c) Copyright PWxyz, LLC. All rights reserved.

(c) Copyright PWxyz, LLC. All rights reserved
Review by Library Journal Review

American science writer Forbes (U.S. Dept. of Defense; Imitation of Life: How Biology Is Inspiring Computing) has coauthored with Mahon (retired, British Govt. Statistical Svc.; The Man Who Changed Everything: The Life of James Clerk Maxwell) an excellent biography of two "discoverers" (in the parlance of their time) who truly brought about the modern scientific age. Daringly, but with exacting experiments and proofs, Faraday (a scientifically adept Englishman) and his contemporary and successor Maxwell (a mathematically adept Scotsman) broke with the long tradition of the mostly mechanical worldview promulgated by Isaac Newton and uncovered much about how electricity and magnetism work. This book is rich in details about the social, scientific, and personal contexts in which these 19th-century geniuses worked, much as Daniel Kevles's The Physicists is about their 20th-century successors and is even more readable than that well-regarded work. The simple diagrams of some of Faraday's and Maxwell's devices, as well as excerpts from their letters, plus some photographic portraits, add further appeal to the title. VERDICT Fans of biographies, as well as anyone interested in science and technology (without these men, we would not have electric motors, televisions, or most of our current electronic devices) will enjoy reading about these "two modest and genial men whose combined endeavors changed the world."-Sara R. Tompson, Jet Propulsion Lab Lib., Pasadena, CA (c) Copyright 2014. Library Journals LLC, a wholly owned subsidiary of Media Source, Inc. No redistribution permitted.

(c) Copyright Library Journals LLC, a wholly owned subsidiary of Media Source, Inc. No redistribution permitted.
Review by Kirkus Book Review

Forbes (Imitation of Life: How Biology Is Inspiring Computing, 2004, etc.) and Mahon (Oliver Heaviside: Maverick Mastermind of Electricity, 2009, etc.) offer a compelling new interpretation of the seminal importance of the discoveries of Michael Faraday (17911861) and James Clerk Maxwell (18311879). The authors explain "the way that Faraday and Maxwell's concept of the electromagnetic field transformed scientists' view of the physical world," beginning with Faraday's anticipation of a unified field theory that would include the force of gravity as well as electromagnetism and the propagation of light. His ideas were so advanced that not only did he reject the Newtonian concept of action-at-distance, then prevalent among scientists, but also the existence of an ether. "From today's perspectiveFaraday, the bold theorist, was making an advance announcement of a scientific transformation that has given us not only electromagnetic theory but special relativity," write the authors. Faraday is credited as the brilliant experimentalist who "discovered the principle of the electric motor," while Maxwell, with his groundbreaking Treatise on Electricity and Magnetism, laid the groundwork for modern field theory. Forbes and Mahon show that Maxwell adhered to Faraday's hypothesis that the propagation of electricity and magnetism in space occurred through the vibration of lines of force. He developed his famous equations by first adapting the mathematical treatment of fluid flow and a mechanical model of spinning cells with minute ball bearings as heuristic models. Only then did he dispense with these models and directly employ the "mathematical laws of dynamics" to electromagnetism, thus laying the basis for modern field theory. The authors emphasize that, for Maxwell, his use of models "didn't purport to represent nature's actual mechanism, it was merely a temporary aid to thought." A lively account of the men and their times and a brilliant exposition of the scientific circumstances and significance of their work.]] Copyright Kirkus Reviews, used with permission.

Copyright (c) Kirkus Reviews, used with permission.

Introduction It is 1888. Picture a large, sparsely furnished room. It has stout wooden tables and workbenches -- a laboratory of some kind -- but there are no retorts, Bunsen burners, or flasks of brightly colored liquid. Instead, the room is stocked with curious metal devices that have strange names: Rhümkorff coils, Knochenhauer spirals, Wheatstone bridges. Their purpose is to probe the ways of the mysterious invisible phenomenon -- electricity. The room has a single occupant, a young man, handsome, neatly suited, and dark-haired with a close-trimmed beard and moustache. He is deftly assembling some apparatus on one of the long wooden tables. At one end he has constructed a circuit that will produce electric sparks across a narrow air gap between two metal spheres connected to the ends of the wires in the circuit. Ordinarily air doesn't conduct electricity but, if the two spheres are close together and the voltage is high enough, a spark will appear to jump across the gap, although it is really a series of very rapid sparks that jump back and forth, or oscillate, between the spheres. To each sphere he has attached a metal rod connected to a rectangular metal plate -- he has learned that this will alter the frequency of oscillation. He presses a key to activate the circuit, and vivid blue sparks crackle across the gap between the spheres. So far, so good; his primary circuit works, as it had the day before and the day before that. He turns his attention to a separate part of the apparatus that he calls his detector -- a simple loop of wire with a very small gap between its ends that he can adjust with a screw. He holds the detector close to the sparking primary circuit, and faint sparks appear across its own gap. This happens, he reasons, when waves of energy pass from the primary circuit to the detector. All this is familiar ground to him, but the next steps are untried and will, he hopes, be decisive ones. Switching off the primary circuit for the moment, he props up a large zinc sheet in a vertical position at the far end of the table. Its purpose is to act as a reflector, like a mirror. He places the detector on the table between the primary circuit and the zinc reflecting sheet, closes the blinds, waits for his eyes to adjust to the darkness, and then switches on his primary circuit. Turning his back on the sparks scintillating between the spheres, he looks for tiny sparks between the terminals of his detector. They appear, faint but unmistakable. Now for the step that will, if successful, establish the result he is seeking. He looks to see if the brightness of the sparks varies as he moves the detector slowly away from the primary circuit toward the reflecting zinc sheet. Indeed, it does. The sparks diminish to nothing, then grow again to their brightest, and then the cycle repeats. He knows that when any kind of wave is reflected back toward its source, it forms a standing wave, which appears to vibrate in place, like a guitar string. Hence, waves are being produced by the primary circuit and reflected by the zinc sheet. This is exactly what he wanted to find. Heinrich Hertz, professor of experimental physics at the Technische Hochschule in Karlsruhe, has made one of the greatest experimental discoveries in the history of science: he has proved beyond doubt the existence of electromagnetic waves. As Guglielmo Marconi and others were soon to show, the commercial value of Hertz's discovery was immense. But he had no notion of this, nor, indeed, of any practical application. What had captivated Hertz and set him on his quest was a beguiling but strange scientific idea -- the brainchild of British experimentalist Michael Faraday in the 1830s that had been raised into a full mathematical theory by the young Scot James Clerk Maxwell three decades later. Their idea was so different from anything that had gone before that many of the leading men of the time dismissed it as a flight of fancy. Others were simply baffled; they did not know what to make of it. But to Hertz it was a beautiful idea that rang true. All it lacked was physical proof, and his quest was to supply experimental evidence that would put the matter beyond dispute. From the time of Newton, leading scientists had believed that the universe was governed by mechanical laws: material objects held energy and inflicted forces. To them, the surrounding space was nothing more than a passive backdrop. The extraordinary idea put forward by Faraday and Maxwell was that space itself acted as a repository of energy and a transmitter of forces: it was home to something that pervades the physical world yet was inexplicable in Newtonian terms  -- the electromagnetic field. Faraday's first notion of lines of force, much derided at the time, grew into Maxwell's sophisticated mathematical theory, which predicted that every time a magnet jiggled, or an electric current was turned on or off, a wave of electromagnetic energy would spread out into space like a ripple on a pond, changing the nature of space itself. Maxwell calculated the speed of the waves from the elementary properties of electricity and magnetism, and it turned out to be the very speed at which light had been measured. He surmised that visible light is just a small band in a vast spectrum of electromagnetic waves, all traveling at the same speed but with wavelengths that might range from nanometers to kilometers. All this remained just a theory with more skeptics than adherents until a quarter of a century later, when Hertz emphatically verified it by producing and detecting what we would now call shortwave radio waves in his laboratory. The door to previously unimaginable regions of scientific knowledge was opened. It is almost impossible to overstate the scale of Faraday and Maxwell's achievement in bringing the concept of the electromagnetic field into human thought. It united electricity, magnetism, and light into a single, compact theory; changed our way of life by bringing us radio, television, radar, satellite navigation, and mobile phones; inspired Einstein's special theory of relativity; and introduced the idea of field equations, which became the standard form used by today's physicists to model what goes on in the vastness of space and inside atoms. Faraday and Maxwell have attracted their share of biographers, and rightly so. Aside from their genius, both were admirable, generous-spirited men who conducted their science with infectious enthusiasm and exuded the kind of charm that made people feel better about themselves and the world in general. But perhaps even more compelling than their individual life stories is the way that the two men from totally different backgrounds -- a self-taught son of a poor blacksmith and a Cambridge-educated son of a Scottish laird -- were brought together by their curiosity about the physical world and their determination to find out how it works. Although they met only late in Faraday's life, they formed a tremendously strong bond -- they were united by their willingness to challenge entrenched scientific customs and conventions. The theory of the electromagnetic field is their joint creation and has its own story, intertwined with theirs and with its own set of diverse supporting characters. There were, for example, the American rake Count Rumford, who was instrumental in founding the Royal Institution, which gave employment to the impecunious, young Faraday; the brilliant but vain Humphry Davy, who was Faraday's inspiring mentor; the maverick Oliver Heaviside, who summarized Maxwell's theory into the four famous "Maxwell's equations"; and the hardworking Oliver Lodge, who discovered waves along wires but found he had been comprehensively scooped by Hertz. Welcome to the story of the electromagnetic field. Excerpted from Faraday, Maxwell, and the Electromagnetic Field: How Two Men Revolutionized Physics by Nancy Forbes, Basil Mahon All rights reserved by the original copyright owners. Excerpts are provided for display purposes only and may not be reproduced, reprinted or distributed without the written permission of the publisher.