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James Prescott Joule (December 24, 1818 - October 11, 1889)
was an English physicist, born in
Salford, near Manchester, England.
James Joule
Joule studied the nature of heat, and discovered its relationship to mechanical work
(see energy). This led to the theory of conservation of energy (the First Law of Thermodynamics). The SI unit of work, the joule, is named after him. He worked with Lord Kelvin to develop the absolute scale of temperature, made observations on magnetostriction, and found the relationship between the flow of current through a resistance and the heat dissipated, now
called Joule's law.
Biography
Early years
The son of a wealthy brewer, Joule was tutored as a young man by the famous scientist John Dalton. Fascinated by electricity, he and his brother
experimented by giving electric shocks to each other and to the family's servants. Joule ran the brewery as an adult, and science
was merely a serious hobby. His work on energy can be traced to his attempt to build an electric motor that would replace steam
engines.
Energy
Joule's ideas about energy were not accepted at first, partly because they depended on extremely precise measurements, which had not previously been common in physics. His best-known
experiment involved the use of a falling weight to spin a paddlewheel in an insulated barrel of water, whose increased
temperature he measured. He claimed to be able to measure temperatures to an accuracy of 1/200 of a degree Fahrenheit, which his contemporaries did not believe
possible. Joule's experiments complemented the theoretical work of Rudolf
Clausius, who is considered by some to be the coinventor of the energy concept.
Further resistance came because Joule's work contradicted the widespread belief that heat was a fluid, the "caloric," that
could be neither created nor destroyed, whereas Joule claimed that heat was only one of many forms of energy, and only the sum of
all the forms was conserved.
Joule was proposing a kinetic theory of heat (he believed it to be a form of rotational, rather then translational, kinetic energy), and this required a conceptual leap: if heat was a form of
molecular motion, why didn't the motion of the molecules gradually die out? Joule's ideas required one to believe that the
collisions of molecules were perfectly elastic. We should also remember that the very existence of atoms and molecules was not widely accepted for another hundred
years.
Although it may be hard today to understand the allure of the caloric
theory, at the time it seemed to have some clear advantages. Carnot's successful theory of heat engines had also been based on the caloric assumption, and
only later was it proved by Lord
Kelvin that Carnot's mathematics were equally valid without assuming a caloric fluid.
Energy conservation
Although the discovery of energy conservation was one of the keystones of the new science of thermodynamics, Joule and his
contemporaries did not initially understand that thermodynamic processes could be irreversible. Instead, they interpreted energy
universe, in which the same processes could be repeated indefinitely by recycling the same energy. This view was only later shown
to be invalid with the discovery of the second
law of thermodynamics and the concept of entropy.
Death and afterwards
Joule died at home in Sale, Greater
Manchester, and, like Dalton with whom he worked, is buried in Westminster Abbey.
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