Benjamin Thompson

Count Rumford (Benjamin Thompson)

Library of Congress

[b. Woburn, Massachusetts, March 26, 1753, d. Auteuil, near Paris, August 21, 1814]

Benjamin Thompson grew up in the American colonies and became a spy for the British, which forced him to flee to England in 1776. He worked for the British government and was knighted by King George III in 1784. He then moved to Munich in southern Germany, where he was made a count of the Holy Roman Empire: Count Rumford.

Rumford's major scientific contribution concerned the nature of heat. At that time it was widely believed that heat is a fluid form of matter. While boring (drilling out) cannons, Rumford discovered that more heat was released than could possibly have been contained in the metal. He concluded that the process of boring produced the heat, and said that heat should be considered a form of motion. Rumford applied his understanding of heat to improving fireplaces so that they better reflected heat and carried away smoke. He invented the kitchen stove, drip coffeepot, pressure cooker, and thermal underwear.

The American-born British physicist Benjamin Thompson, Count Rumford (1753-1814), is best known for his attacks on the caloric theory of heat.

Benjamin Thompson was born on March 26, 1753, in Woburn, Mass. He received only 2 years of formal education and at 13 was apprenticed to a local merchant. At the age of 19, while teaching in Concord, N.H., he married a wealthy widow, 14 years his senior. He thus acquired not only an extensive estate but social and political influence as well.

Thompson's open support of the British crown, however, made his position increasingly precarious as political tensions mounted in the Colonies. As a result of his loyalist activities, he was forced in December 1774 to flee to Boston, abandoning his wife and infant daughter. He spent the next 15 months actively spying for the British government, supplying them with detailed reports on the condition and activities of the assembling colonial forces. When the British abandoned Boston in March 1776, Thompson departed for London.

Thompson arrived in London a confident, aggressive young man with a very useful knowledge of the colonial military situation; within 4 years he had risen to the position of undersecretary of state for colonial affairs. He also found time to pursue his scientific interests, and he soon gained a reputation as a productive natural philosopher as well. He undertook a series of studies on the explosive force of gunpowder, and his published report of these experiments was influential in his election as a fellow of the Royal Society in 1781. In that year he suddenly left London and returned to the Colonies, where he spent an undistinguished 2 years as a commanding officer in the British forces. He then returned to London and from there set out for the Continent.

Social Reform

In 1784 Thompson settled down in Munich as an aidede-camp and confidential adviser to Elector Karl Theodor of Bavaria. Thompson did much to advance the stature of the Bavarian court by promoting scientific and technological advances and by instituting reform in the military, educational, and economic structure of the country. His standing was such as to guarantee him both the financial and technical support necessary for his varied, and often grandiose, projects, and in return for his activities he was in 1793 made a count of the Holy Roman Empire. He chose as his title Count Rumford, Rumford being the original name of Concord, N.H.

While in Munich one of Rumford's chief responsibilities was reorganizing the Bavarian army. In an effort to find more efficient and economical means of feeding and clothing the troops, he undertook an extensive study of the thermal conductivity of various types of cloth, in the process discovering the principle of heat transfer through what are today known as convection currents. Unable to persuade any commercial manufacturer to adopt the results of this research, Rumford set up what he called a "military work-house" for producing the new military uniforms and in so doing became actively involved in social reform. Munich at the time was noted for its swarms of beggars, and on New Year's Day, 1790, Rumford had the Bavarian army arrest and jail every beggar in the city. These were then trained in his workhouse to manufacture the desired uniforms and in return for their labor received shelter, food, and education. The operation of this workhouse also involved Rumford in the associated practical problems of nutrition, heating, and lighting.

Theory of Heat

Rumford is best known today, however, for his contributions to the theory of heat. At the end of the 18th century the predominant theory of heat was the so-called caloric theory, according to which heat was a fluid substance that flowed into bodies when they were heated and flowed out of them as they cooled. The success of this theory in explaining then known phenomena is reflected in many terms, such as "heat flow" and "calorie," still used by physicists today. During his earlier gunpowder studies, however, Rumford had observed certain anomalies which the caloric theory seemed unable to explain, and for the remainder of his life he was constantly on the lookout for additional experimental evidence which might refute this theory.

Rumford's famous cannon-boring experiments present perhaps the most graphic evidence. One of his positions in Munich was inspector general of artillery for the Bavarian army, and, in the course of supervising work in the Munich arsenal, he was struck by the large amount of heat produced in boring a brass cannon. He devised an experiment in which, by utilizing a blunt borer to maximize the heat produced, he was able to boil large quantities of water with the resultant heat. The important aspect of this experiment, as Rumford himself noted, was the seemingly endless supply of heat that could be thus produced. According to the caloric theory, the boring tool produced heat by squeezing the caloric fluid out of the bodies rubbed together, but, as Rumford pointed out, anything which could be produced without limitation could not be a material substance such as caloric fluid. It should be emphasized, however, that although Rumford also produced numerous other experiments to refute the caloric theory, these experiments did not alone disprove the caloric theory, and not until much later in the 19th century was the concept of heat as a mode of motion generally adopted.

Royal Institution and Later Life

Rumford's position in Munich had always been somewhat precarious. His privileged status, the rapidity and success of his numerous innovations, and his ruthless disdain for his political opponents did nothing to silence the clamor of his enemies, and in 1798 the elector found it expedient to appoint him minister plenipotentiary to England, a position of honor which nonetheless effectively removed him from Munich politics. Arriving in London, he discovered that George III refused to accept a British subject (which Rumford still was) as minister from a foreign country.

Finding himself without a job, Rumford settled down in London to the task of establishing the Royal Institution. Justly renowned today for its research and popular lectures, the institution at its founding was part science museum and part technical school, reflecting Rumford's concern for the practical application of his researches. In 1801, after financial and personality difficulties, Rumford dissociated himself from the institution.

In 1804 Rumford moved to Paris and there, the following year, married Madame Lavoisier, the widow of the famous French chemist. A fashionable, though discordant, marriage, it lasted but 2 years, and in 1807 Rumford retired to the village of Auteuil near Paris. He became a member of the National Institute of France, as the Academy of Sciences was then called, and was a frequent contributor to its sessions and debates, as well as actively working to adapt his theoretical researches to practical applications. He died at Auteuil on Aug. 21, 1814.

Further Reading

A new edition of Rumford's works is being edited by Sanborn C. Brown, Collected Works of Count Rumford, of which volume 1 is The Nature of Heat (1968). Of the full-length biographies the reader may most profitably consult W. J. Sparrow, Knight of the White Eagle: A Biography of Sir Benjamin Thompson, Count Rumford (1964). Sanborn C. Brown, Count Rumford: Physicist Extraordinary (1962), is an excellent, brief account. Other studies are James A. Thompson, Count Rumford of Massachusetts (1935), and Egon Larsen, An American in Europe (1953).

Additional Sources

Brown, Sanborn Conner, Benjamin Thompson, Count Rumford, Cambridge, Mass.: MIT Press, 1979.

Brown, Sanborn Conner, Count Rumford, physicist extraordinary, Westport, Conn.: Greenwood Press, 1979, 1962.

Dabney, Betty Page, The silver sextant: four men of the Enlightenment, Norfolk, Va.: B.P. Dabney, 1993.

Jones, Bence, The Royal Institution, its founder and its first professors, New York: Arno Press, 1975.

British-American soldier, scientist, inventor, philanthropist, administrator, and universal man. As a Loyalist, he settled in England, was elected a Fellow of the Royal Society, and decided to further his military career by fighting the Turks in Europe. Settling in Munich, he became Minister of War, Minister of Police, and Grand Chamberlain to the Elector of Bavaria. He reorganized the Bavarian Army, did much to improve the condition of the labouring classes, and suppressed mendicity. In 1791 he was created a Count of the Holy Roman Empire, taking the title Rumford from the township in America to which his first wife's family belonged (now Concord, NH). He concerned himself also with improvements to fireplace-construction and the reduction of pollution from chimneys, and did much to reform hospitals and workhouses in Ireland. With Sir Joseph Banks (1743–1820) he founded the Royal Institution of Great Britain (1799), and himself made the first sketches (now in the RIBA) for the lecture-room of the Institution at 20–21 Albermarle Street, London. In Munich a large tract of land belonging to the Elector Karl Theodor of Bavaria (reigned 1777–99) was transformed at Rumford's instigation, the designer being Sckell: it is known as the Englischer Garten, is one of the very first public parks designed as such, and is in the Picturesque English landscape garden style. Rumford published his thoughts on the benefits of public parks in his Essays Political, Economical, and Philosophical (1796–1802), an American edition of which appeared in 1798–1804, and a German in 1797–8. His work proved to be a considerable influence on Downing, Olmsted, and others. In 1805 Rumford took as his second wife Marie-Anne Pierret Paulze (1758–1836), widow of the distinguished French scientist, Antoine-Laurent Lavoisier (1743–94—guillotined during the Terror).

Bibliography

• EB (1959)
• Oxford Dictionary of National Biography (2004)

The full bibliography for this book is available to download as a pdf file.
Download the bibliography for A Dictionary of Architecture and Landscape Architecture (PDF: 1.2MB)

For other persons named Benjamin Thompson, see Benjamin Thompson (disambiguation).

Benjamin Thompson
Born	March 26, 1753(1753-03-26) Woburn, Massachusetts
Died	August 21, 1814 (aged 61) Paris
Residence	Woburn, Massachusetts, England, Germany (Bavaria), and France
Citizenship	United Kingdom
Nationality	British
Fields	Physics
Known for	Thermodynamics
Notable awards	Copley Medal
Religious stance	Anglican

Sir Benjamin Thompson, Count Rumford (in German: Reichsgraf von Rumford), FRS (March 26, 1753 – August 21, 1814) was an Anglo-American physicist and inventor whose challenges to established physical theory were part of the 19th century revolution in thermodynamics.

Contents 1 Early life in America 2 Bavarian maturity 2.1 Experiments on heat 2.2 Mechanical equivalent of heat 2.3 Fireplaces and coffee pots 2.4 Light and photometry 3 Later life 4 Honours 5 See also 6 Notes 7 Further reading 8 Bibliography 9 External links

Early life in America

Thompson was born in rural Woburn, Massachusetts, on March 26, 1753; his birthplace is preserved as a museum. He was educated mainly at the village school, although he sometimes walked to Cambridge with the older Loammi Baldwin to attend lectures by Professor John Winthrop at Harvard College. At the age of 13 he was apprenticed to John Appleton, a merchant of nearby Salem. Thompson excelled at his trade, and coming in contact with refined and well educated people for the first time, adopted many of their characteristics, including an interest in science. While recuperating in Woburn in 1769 from an injury, Thompson conducted experiments concerning the nature of heat and began to correspond with Loammi Baldwin and others about them. Later that year, he worked for a few months for a Boston shopkeeper and then apprenticed himself briefly, and unsuccessfully, to a doctor in Woburn.

Thompson's prospects were dim in 1772 but in that year they changed abruptly. He met, charmed and married a rich and well-connected heiress named Sarah Rolfe, moved to Portsmouth, New Hampshire, and through his wife's influence with the governor, was appointed a major in a New Hampshire Militia.

When the American Revolution began, Thompson was a man of property and standing in New England, and was opposed to the rebels. He was active in recruiting loyalists to fight the rebels. This earned him the enmity of the popular party, and a mob attacked Thompson's house. He fled to the British lines, abandoning his wife, as it turned out, forever. Thompson was welcomed by the British, to whom he gave valuable information about the American forces, and became an advisor to both General Gage and Lord George Germain.

While working with the British armies in America, he conducted experiments concerning the force of gunpowder, the results of which were widely acclaimed when eventually published, in 1781, in the Philosophical Transactions of the Royal Society.^[1] Thus, when he moved to London at the conclusion of the war, he already had a reputation as a scientist.

Bavarian maturity

The beer garden "Am chinesischen Turm" in the Englischer Garten in Munich

In 1785, he moved to Bavaria where he became an aide-de-camp to the Prince-elector Karl Theodor. He spent eleven years in Bavaria, reorganising the army and establishing workhouses for the poor. During his work he also invented the Rumford Soup, a nutritious soup for the poor, and established the cultivation of the potato in Bavaria. He studied methods of cooking, heating, and lighting, including the relative costs and efficiencies of wax candles, tallow candles, and oil lamps.^[2] He also founded the Englischer Garten in Munich in 1789; it remains today and is known as one of the largest urban public parks in the world.

Experiments on heat

His experiments on gunnery and explosives led to an interest in heat. He devised a method for measuring the specific heats of solids but was disappointed that Johan Wilcke had priority.

Thompson next investigated the insulating properties of various materials including fur, wool and feathers. He correctly appreciated that the insulating properties of these natural materials arise from the fact that they inhibit the convection of air. He then made the somewhat reckless, and incorrect, inference that air and, in fact, all gases, were perfect non-conductors of heat.^[3][4] He further saw this as evidence of the argument from design, contending that divine providence had arranged for fur on animals in such a way as to guarantee their comfort.

In 1797, he extended his claim about non-conductivity to liquids.^[5] The idea raised considerable objections from the scientific establishment, John Dalton^[6] and John Leslie^[7] making particularly forthright attacks. Instrumentation far exceeding anything available in terms of accuracy and precision would have been needed to verify Thompson's claim. Again, he seems to have been influenced by his theological beliefs^[8] and it is likely that he wished to grant water a privileged and providential status in the regulation of human life.^[9]

Mechanical equivalent of heat

However, Rumford's most important scientific work took place in Munich, and centred on the nature of heat, which he contended in An Experimental Enquiry Concerning the Source of the Heat which is Excited by Friction (1798) was not the caloric of then-current scientific thinking but a form of motion. Rumford had observed the frictional heat generated by boring cannon at the arsenal in Munich. Rumford immersed a cannon barrel in water and arranged for a specially blunted boring tool. He showed that the water could be boiled within roughly two and a half hours and that the supply of frictional heat was seemingly inexhaustible. Rumford confirmed that no physical change had taken place in the material of the cannon by comparing the specific heats of the material machined away and that remaining.

Rumford argued that the seemingly indefinite generation of heat was incompatible with the caloric theory. He contended that the only thing communicated to the barrel was motion.

Rumford made no attempt to further quantify the heat generated or to measure the mechanical equivalent of heat. Though this work met with a hostile reception, it was subsequently important in establishing the laws of conservation of energy later in the 19th century.

Fireplaces and coffee pots

Section of Rumford fire place

Rumford's coffee percolator

Thompson was an active and prolific inventor, developing improvements for chimneys and fireplaces and inventing the double boiler, a kitchen range, and a drip coffeepot. The Rumford fireplace is a much more efficient way to heat a room than earlier fireplaces, and created a sensation in London when he introduced the idea of restricting the chimney opening to increase the updraught. He and his workers changed fireplaces by inserting bricks into the hearth to make the side walls angled and added a choke to the chimney to increase the speed of air going up the flue. It effectively produced a streamlined air flow, so all the smoke would go up into the chimney rather than lingering, entering the room and often choking the residents. It also had the effect of increasing the efficiency of the fire, and gave extra control of the rate of combustion of the fuel, whether wood or coal. Many fashionable London houses were modified to his instructions, and became smoke-free. Thompson became a celebrity when news of his success became widespread.

His work was also very profitable, and much imitated when he published his analysis of the way chimneys worked. In many ways, he was similar to Benjamin Franklin, who also invented a new kind of heating stove based on a new way of controlling the air flow into and through the furnace.

He invented a percolating coffee pot following his pioneering work with the Bavarian Army, where he improved the diet of the soldiers as well as their clothes. His work for the army was rewarded by being made Count Rumford.

To understand the significance of Rumford's work in the context of the development of thermodynamics, see timeline Edit

The retention of heat is something of a leitmotif, as he is also credited with the invention of thermal underwear^[10].

Light and photometry

Rumford was a pioneer of photometry, the measurement of light. He invented a photometer and introduced the standard candle, the predecessor of the candela, as a unit of luminous intensity. His standard candle was made from the oil of a sperm whale, to rigid specifications.^[11]

Later life

Satirical cartoon by James Gillray showing a Royal Institution lecture on pneumatics with Davy holding the bellows and Count Rumford looking on at extreme right. Dr Garnett is the lecturer holding the victim's nose

After 1799, he divided his time between France and England. With Sir Joseph Banks, he established the Royal Institution of Great Britain in 1799. The pair chose Sir Humphry Davy as the first lecturer. The institution flourished and became world famous as a result of Davy's pioneering research. His assistant, Michael Faraday established the Institution as a premier research laboratory, and also justly famous for its series of public lectures popularizing science. That tradition continues to the present, and the Royal Institution Christmas lectures attract large audiences through their TV broadcasts.

Thompson endowed the Rumford medals of the Royal Society and the American Academy of Arts and Sciences, and endowed a professorship at Harvard University. In 1803, he was elected a foreign member of the Royal Swedish Academy of Sciences.

In 1804, he married Marie-Anne Lavoisier, the widow of the great French chemist Antoine Lavoisier, his American wife having died since his emigration. They soon separated, but Thompson settled in Paris and continued his scientific work until his death on August 21, 1814. With his first wife Thompson had a daughter, Sarah Thompson, who inherited his title. Thompson is buried in the small cemetery of Auteuil in Paris, just across from Adrien-Marie Legendre.

Honours

• Colonel, Kings American Dragoons
• Knighted, 1784.
• Count of the Holy Roman Empire 1791
• The crater Rumford on the Moon is named after him.
• Rumford baking powder (patented 1859) is named after him, having been invented by a former Rumford professor at Harvard University, Eben Norton Horsford (1818-1893), cofounder of the Rumford Chemical Works of East Providence RI.

See also

Wikisource has the text of the 1911 Encyclopædia Britannica article Rumford.

• Benjamin Thompson House
• Heat
• History of thermodynamics
• Royal Institution

Notes

Grave of Count Rumford (Paris)

1. ^ Benjamin Thompson (1781). "New Experiments upon Gun-Powder, with Occasional Observations and Practical Inferences". Philosophical Transactions of the Royal Society of London 71: 229–328. doi:10.1098/rstl.1781.0039. http://links.jstor.org/sici?sici=0261-0523%281781%2971%3C229%3ANEUGWO%3E2.0.CO%3B2-B. 
2. ^ "Lamp". The Encyclopedia Americana. 16. Encyclopedia Americana Corp. 1919. p. 681. http://books.google.com/books?id=IbZPAAAAMAAJ&pg=PA681&dq=benjamin-thompson++wax+candle&lr=&as_brr=3&as_pt=ALLTYPES&ei=HlR5SbamGpPOkATt8fXqBg. 
3. ^ Rumford (1786) "New experiments upon heat" Philosophical Transactions of the Royal Society p.273
4. ^ Rumford (1792) "Experiments upon heat" Philosophical Transactions of the Royal Society p.48-80
5. ^ Rumford (1797) "On the propagation of heat in fluids" Nicholson's Journal 1 pp298-341
6. ^ Cardwell (1971) p.99
7. ^ Leslie, J. (1804). An Experimental Enquiry into the Nature and Propagation of Heat. London. 
8. ^ Rumford (1804) "An enquiry concerning the nature of heat and the mode of its communication" Philosophical Transactions of the Royal Society p.77
9. ^ Cardwell (1971) p.102
10. ^ Prof. Michael Fowler of the University of Virginia, lecture notes: [1], and Have I Got News For You, first transmitted December 16, 2005, BBC1.
11. ^ Waldemar Karwowski (2006). International Encyclopedia of Ergonomics and Human Factors. CRC Press. p. 1478. ISBN 9780415304306. http://books.google.com/books?id=tl5YAj10BcsC&pg=PA1478&dq=benjamin-thompson++photometry+candle&lr=&as_brr=3&as_pt=ALLTYPES&ei=r1l5SY6PIJCQkQSV99DpBg. 

Further reading

• Collected Works of Count Rumford, Harvard University Press, Edited by Sanborn C. Brown:
  • Collected Works of Count Rumford, Volume I, The Nature of Heat, (1968).
  • Collected Works of Count Rumford, Volume II, Practical Applications of Heat, (1969).
  • Collected Works of Count Rumford, Volume III, Devices and Techniques, (1969).
  • Collected Works of Count Rumford, Volume IV, Light and Armament, (1970).
  • Collected Works of Count Rumford, Volume V, Public Institutions, (1970).

Bibliography

Statue of Thompson outside the library of his hometown, Woburn, Massachusetts. (A copy of the original in Munich.)

• Brown, Sanborn C. (1962). Count Rumford: Physicist Extraordinary. Doubleday & Co. 
• Bradley, D. (1967). Count Rumford. Van Nostrand. ISBN B0000CM48T. 
• Brown, G.I. (2001). Count Rumford: The Extraordinary Life of a Scientific Genius - Scientist, Soldier, Statesman, Spy. Sutton Publishing. ISBN 0-262-02138-2. 
• Brown, S.C. (1981). Benjamin Thompson, Count Rumford. Cambridge USA: MIT Press. ISBN 0-262-02138-2. 
• Cardwell, D.S.L. (1971). From Watt to Clausius: The Rise of Thermodynamics in the Early Industrial Age. London: Heinemann. pp. 95–107. ISBN 0-435-54150-1. 
• Larsen, E. (1953). An American in Europe: The life of Benjamin Thompson, Count Rumford. Rider. ISBN B0000CII01. 
• Orton, V. (2000). The Forgotten Art of Building a Good Fireplace: The Story of Sir Benjamin Thompson, Count Rumford, an American Genius & His Principles of Fireplace Design Which Have Remained Unchanged for 174 Years. Alan C. Hood and Company Inc. ISBN 0-911469-17-6. 
• Sparrow, W.J. (1964). Knight of the White Eagle: A biography of Sir Benjamin Thompson, Count Rumford, 1753-1814. Hutchinson. ISBN B0000CM48T. 

External links

• Eric Weisstein's World of Science. "Rumford, Benjamin Thompson". (1753-1814)
• Dr. Hugh C. Rowlinson "The Contribution of Count Rumford to Domestic Life in Jane Austen’s Time" An article not only detailing the Rumford fireplace, but also Rumford's life and other achievements.
• Works by Benjamin Thompson (Benjamin, Graf von Rumford) at Project Gutenberg
• A Biography of Benjamin Thompson, Jr. Written in 1868
• Escutcheons of Science
• Woburn Historical Society: Count Rumford's Birth Place and Museum
• Count Rumford website

Political offices
Preceded by W. Knox T. De Grey	Under-Secretary of State for the Colonies with W. Knox 1780 – 1781	Succeeded by W. Knox J. Fisher
Awards and achievements
Preceded by James Rennell and Jean-André Deluc	Copley Medal 1792	Succeeded by Alessandro Volta

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