Microscopy Pioneers Pioneers in Optics: Charles Wheatstone
Michael W. Davidson National High Magnetic Field Laboratory , Florida State University , Tallahassee , FL 32306
davidson@magnet.fsu.edu
Charles Wheatstone (1802–1875)
Charles Wheatstone was a prominent nineteenth- century physicist who made signifi cant contributions to a number of areas without having ever received a formal scientifi c education. He was partic- ularly infl uential in the fi eld of optics, where he revolutionized contemporary notions of vision and spatial perception. Born February 6, 1802, in Gloucester, England, Wheatstone entered into an extended family that built and sold musical instruments. He was reared in the family trade, serving an apprenticeship with an uncle who manufactured string instru- ments. Extremely curious and inventive in his youth, Wheatstone began his independent scientifi c development through avid reading and by carrying out experiments in acoustics. In 1821, Wheatstone garnered a considerable amount of public attention by devising what was commonly referred to as the enchanted lyre. Part of an innovative acoustic show, the lyre was attached to the soundboards of a piano and other musical instruments in an upstairs room via a thin steel wire. When Wheatstone or another musician played music upstairs, the sound conduction and the sympathetic resonance of the strings made the lyre appear as if it were magically playing by itself. The feat was particularly important in the life of Wheatstone because it brought him into contact with renowned Danish scientist Christian Oersted who wanted to meet the man who devised it. When he found that his new acquaintance had carried out a number of experiments similar to his own, he encouraged Wheatstone to write a paper that reported his findings. The resulting work entitled New Experiments in Sound became Wheatstone’s first scientific publication.
By 1834 Wheatstone had built such a reputation for himself that he was appointed professor of experimental physics at King’s College in London. However, he proved to be a poor teacher, due to his innate shyness, and rarely lectured, although he retained the post for the rest of his life. Wheatstone’s poor presentation ability also often
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prevented him from reading his own papers to academic societies. Instead, he frequently depended on his close friend and fellow scientist Michael Faraday to adequately portray his ideas.
No matter how lackluster his speaking skills, however, Wheatstone was a brilliant scientist. Intensely interested in electricity, in 1834 he made the first measurement of the velocity of an electrical current passing through a wire by using a rotating mirror. He later suggested that the same device be used to measure the speed of light. Wheatstone’s other significant contributions in the field include improvements to the dynamo, the invention of an adjustable resistor known as the rheostat, and popular- izing a method of measuring electrical resistance invented by Samuel Christie, which came to be known as the Wheatstone bridge.
Wheatstone was also highly concerned with optics, a field he originally entered because of his interest in expressing acoustic phenomena visually. His various studies and experiments led him to develop the theory of stereoscopic vision, which involves the idea that each eye sees a slightly different view of a single scene, which combine in a way that results in depth perception. He then used his new understanding of vision to invent the stereo- scope, which he presented to the Royal Society in 1838. The instrument was designed so that it could present a slightly different two-dimensional image to each eye, which the viewer would then interpret as a single three-dimensional picture. Primarily used for entertainment purposes, various versions of the stereoscope became extremely popular in Victorian England.
During the same period that he was developing his ideas regarding vision, Wheatstone was busily designing the fi rst viable telegraph system in conjunction with William Cooke. T e pair patented the fi ve-needle telegraph and publicly demonstrated the device in 1837. T ough theirs was the fi rst operational commercial electric telegraph, it was later replaced by simpler technology, such as one invented by Samuel Morse. However, the partners made improvements on their system for many years to come. In fact, when Wheatstone died of bronchitis on October 19, 1875, he was in Paris on a business trip promoting his latest developments to French telegraph authorities.
doi: 10.1017/S155192951500053X
www.microscopy-today.com • 2015 July
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