Josiah Willard Gibbs: Difference between revisions
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'''Josiah Willard Gibbs''' ([[February 11]], [[1839]] – [[April 28]], [[1903]]) was an [[United States|American]] [[ |
'''Josiah Willard Gibbs''' ([[February 11]], [[1839]] – [[April 28]], [[1903]]) was an [[United States|American]] theoretical [[physicist]] and [[chemist]], and [[mathematician]]. One of the greatest American scientists of all ime, he devised much of the theoretical foundation for [[chemical thermodynamics]] as well as [[physical chemistry]]. As a [[mathematics|mathematician]], he invented [[Vector calculus|vector analysis]] (independently of [[Oliver Heaviside]]). It is in good part thanks to Gibbs that much of physical and chemical theory has since been exposited using vector analysis. [[Yale University]] awarded Gibbs the first American [[Ph.D.]] in [[engineering]] in 1863, and he spent his entire career at Yale.<ref>{{cite book | last = Wheeler | first = Lynde, Phelps | title = Josiah Willard Gibbs - the History of a Great Mind | publisher = Ox Bow Press | year = 1951 | id = ISBN 1-881987-11-6}}</ref> |
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As one of the greatest American scientists, he devised much of the theoretical foundation for [[chemical thermodynamics]] as well as [[physical chemistry]]. As a [[mathematics|mathematician]], he was an inventor of [[Vector calculus|vector analysis]]. He spent his entire career at Yale, which awarded him the first American [[Ph.D.]] in [[engineering]] in 1863.<ref>{{cite book | last = Wheeler | first = Lynde, Phelps | title = Josiah Willard Gibbs - the History of a Great Mind | publisher = Ox Bow Press | year = 1951 | id = ISBN 1-881987-11-6}}</ref> In 1880, for his work in [[heat]], Gibbs was awarded the [[Rumford Prize]] by the [[American Academy of Arts and Sciences]].<ref>{{cite book | last = Müller | first = Ingo | title = A History of Thermodynamics - the Doctrine of Energy and Entropy | publisher = Springer | year = 2007 | id = ISBN 978-3-540-46226-2}}</ref> |
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In 1901, Gibbs was awarded the [[Copley |
In 1901, Gibbs was awarded the highest possible honor granted by the international scientific community of his day, granted to only one scientist each year: the [[Copley Medal]] of the [[Royal Society of London]], for being "the first to apply the [[second law of thermodynamics]] to the exhaustive discussion of the relation between chemical, electrical, and thermal energy and capacity for external work."<ref>[http://www.1911encyclopedia.org/Josiah_Willard_Gibbs Josiah Willard Gibbs] - Britannica 1911</ref> This quotation summarizes Gibbs's greatest scientific contribution. |
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==Biography== |
==Biography== |
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In 1863, Gibbs was awarded the first [[Doctor of Philosophy|Ph.D. degree]] in [[engineering]] in the USA from the [[Sheffield Scientific School]] at Yale. He then tutored at Yale, two years in Latin and one year in what was then called [[natural philosophy]], now comparable to the natural sciences, particularly physics. In [[1866]] he went to [[Europe]] to study, spending a year each at [[Paris]], [[Berlin]], and [[Heidelberg]], where he was influenced by [[Gustav Kirchhoff|Kirchhoff]] and [[Hermann von Helmholtz|Helmholtz]]. At the time, German academics were the leading authorities in [[chemistry]], [[thermodynamics]], and theoretical natural science in general. These three years account for nearly all of his life spent outside New Haven. |
In 1863, Gibbs was awarded the first [[Doctor of Philosophy|Ph.D. degree]] in [[engineering]] in the USA from the [[Sheffield Scientific School]] at Yale. He then tutored at Yale, two years in Latin and one year in what was then called [[natural philosophy]], now comparable to the natural sciences, particularly physics. In [[1866]] he went to [[Europe]] to study, spending a year each at [[Paris]], [[Berlin]], and [[Heidelberg]], where he was influenced by [[Gustav Kirchhoff|Kirchhoff]] and [[Hermann von Helmholtz|Helmholtz]]. At the time, German academics were the leading authorities in [[chemistry]], [[thermodynamics]], and theoretical natural science in general. These three years account for nearly all of his life spent outside New Haven. |
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In [[1869]], he returned to [[Yale University|Yale]] and was appointed Professor of [[Mathematical Physics]] in 1871, the first such professorship in the United States and a position he held for the rest of his life. The appointment was unpaid at first, a situation common in Germany and otherwise not unusual at the time, because Gibbs had yet to publish anything. Between [[1876]] and [[1878]] Gibbs wrote a series of papers |
In [[1869]], he returned to [[Yale University|Yale]] and was appointed Professor of [[Mathematical Physics]] in 1871, the first such professorship in the United States and a position he held for the rest of his life. The appointment was unpaid at first, a situation common in Germany and otherwise not unusual at the time, because Gibbs had yet to publish anything. Between [[1876]] and [[1878]] Gibbs wrote a series of papers on the graphical analysis of multi-phase chemical systems. These were eventually published together in a monograph titled ''On the Equilibrium of Heterogeneous Substances'', his most renowned work. It is now deemed one of the greatest scientific achievements of the [[19th century]], and one of the foundations of [[physical chemistry]]. In these papers Gibbs applied [[thermodynamics]] to interpret physicochemical phenomena, successfully explaining and interrelating what had previously been a mass of isolated facts. |
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<blockquote>"It is universally recognised that its publication was an event of the first importance in the history of [[chemistry]]. ... Nevertheless it was a number of years before its value was generally known, this delay was due largely to the fact that its mathematical form and rigorous deductive processes make it difficult reading for anyone, and especially so for students of [[experiment]]al chemistry whom it most concerns... " (J J O'Connor and E F Robertson, ''[http://www.shsu.edu/~icc_cmf/bio/gibbs.html J. Willard Gibbs]'')</blockquote> |
<blockquote>"It is universally recognised that its publication was an event of the first importance in the history of [[chemistry]]. ... Nevertheless it was a number of years before its value was generally known, this delay was due largely to the fact that its mathematical form and rigorous deductive processes make it difficult reading for anyone, and especially so for students of [[experiment]]al chemistry whom it most concerns... " (J J O'Connor and E F Robertson, ''[http://www.shsu.edu/~icc_cmf/bio/gibbs.html J. Willard Gibbs]'')</blockquote> |
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After 1889, he worked on [[statistical mechanics]], laying a foundation and "providing a mathematical framework for [[Quantum mechanics|quantum theory]] and for [[James Clerk Maxwell|Maxwell's]] [[Theory|theories]]" <ref>J. J. O'Connor and E. F. Robertson, "''[http://www.shsu.edu/~icc_cmf/bio/gibbs.html J. Willard Gibbs]''".</ref> He wrote classic textbooks on [[statistical mechanics]], which Yale published in [[1902]]. Gibbs also contributed to [[crystallography]] and applied his vector methods to the determination of [[planet]]ary and [[comet]] [[orbit]]s. |
After 1889, he worked on [[statistical mechanics]], laying a foundation and "providing a mathematical framework for [[Quantum mechanics|quantum theory]] and for [[James Clerk Maxwell|Maxwell's]] [[Theory|theories]]" <ref>J. J. O'Connor and E. F. Robertson, "''[http://www.shsu.edu/~icc_cmf/bio/gibbs.html J. Willard Gibbs]''".</ref> He wrote classic textbooks on [[statistical mechanics]], which Yale published in [[1902]]. Gibbs also contributed to [[crystallography]] and applied his vector methods to the determination of [[planet]]ary and [[comet]] [[orbit]]s. |
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Not much is known about the names and careers of Gibbs's students. |
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Information about the names and careers of Gibbs's students is not readily available, yet one of his protegés was [[Edwin Bidwell Wilson]], who in turn passed his Gibbsian knowledge onto [[Paul Samuelson]].<ref name="Samuelson" /> He is known to have strongly influenced the education of the economist [[Irving Fisher]], who completed a Yale Ph.D. in 1896. |
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Gibbs never married, living all his life in his childhood home with a sister and his brother-in-law, the Yale librarian. His focus on science was such that he was generally unavailable personally. His [[protégé]] E.B. Wilson explains: "Except in the classroom I saw very little of Gibbs. He had a way, toward the end of the afternoon, of taking a stroll about the streets between his study in the old Sloane Laboratory and his home -- a little exercise between work and dinner -- and one might occasionally come across him at that time." Gibbs died in New Haven and is buried in [[Grove Street Cemetery]]. |
Gibbs never married, living all his life in his childhood home with a sister and his brother-in-law, the Yale librarian. His focus on science was such that he was generally unavailable personally. His [[protégé]] E.B. Wilson explains: "Except in the classroom I saw very little of Gibbs. He had a way, toward the end of the afternoon, of taking a stroll about the streets between his study in the old Sloane Laboratory and his home -- a little exercise between work and dinner -- and one might occasionally come across him at that time." Gibbs died in New Haven and is buried in [[Grove Street Cemetery]]. |
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Recognition was slow in coming, in part because Gibbs published mainly in the ''Transactions of the Connecticut Academy of Sciences'', a journal edited by his librarian brother-in-law, little read in the USA and even less so in [[Europe]]. At first, only a few European [[theoretical physics|theoretical physicists]] and [[chemistry|chemists]], such as the [[Scotland|Scot]] [[James Clerk Maxwell]], paid any attention to his work. Only when Gibbs's papers were translated into [[German language|German]] (then the leading language for chemistry) by [[Wilhelm Ostwald]] in 1892, and into [[French language|French]] by [[Henri Louis le Chatelier]] in [[1899]], did his ideas receive wide currency in Europe. His theory of the phase rule was experimentally validated by the works of [[Hendrik Willem Bakhuis Roozeboom|H. W. Bakhuis Roozeboom]], who showed how to apply it in a variety of situations, thereby assuring it of widespread use. |
Recognition was slow in coming, in part because Gibbs published mainly in the ''Transactions of the Connecticut Academy of Sciences'', a journal edited by his librarian brother-in-law, little read in the USA and even less so in [[Europe]]. At first, only a few European [[theoretical physics|theoretical physicists]] and [[chemistry|chemists]], such as the [[Scotland|Scot]] [[James Clerk Maxwell]], paid any attention to his work. Only when Gibbs's papers were translated into [[German language|German]] (then the leading language for chemistry) by [[Wilhelm Ostwald]] in 1892, and into [[French language|French]] by [[Henri Louis le Chatelier]] in [[1899]], did his ideas receive wide currency in Europe. His theory of the phase rule was experimentally validated by the works of [[Hendrik Willem Bakhuis Roozeboom|H. W. Bakhuis Roozeboom]], who showed how to apply it in a variety of situations, thereby assuring it of widespread use. |
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Gibbs was even less appreciated in his native America. Nevertheless, he was recognised as follows: |
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* In 1880, the [[American Academy of Arts and Sciences]] awarded Gibbs its [[Rumford Prize]] for his work in [[heat]].<ref>{{cite book | last = Müller | first = Ingo | title = A History of Thermodynamics - the Doctrine of Energy and Entropy | publisher = Springer | year = 2007 | id = ISBN 978-3-540-46226-2}}</ref> |
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During his lifetime, American |
During his lifetime, American colleges and secondary schools emphasized classics rather than science, and students took little interest in his Yale lectures. (That scientific teaching and research are a fundamental part of the modern university emerged in Germany during the 19th century and only gradually spread from there to the USA.) Gibbs's position at Yale and in American science generally has been described as follows: |
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<blockquote>"In his later years he was a tall, dignified gentleman, with a healthy stride and ruddy complexion, performing his share of household chores, approachable and kind (if unintelligible) to students. Gibbs was highly esteemed by his friends, but American science was too preoccupied with practical questions to make much use of his profound theoretical work during his lifetime. He lived out his quiet life at Yale, deeply admired by a few able students but making no immediate impress on American science commensurate with his genius." (Crowther 1969: nnn)</blockquote> |
<blockquote>"In his later years he was a tall, dignified gentleman, with a healthy stride and ruddy complexion, performing his share of household chores, approachable and kind (if unintelligible) to students. Gibbs was highly esteemed by his friends, but American science was too preoccupied with practical questions to make much use of his profound theoretical work during his lifetime. He lived out his quiet life at Yale, deeply admired by a few able students but making no immediate impress on American science commensurate with his genius." (Crowther 1969: nnn)</blockquote> |
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This is not to say that Gibbs was unknown in his day. For example, the mathematician [[Gian-Carlo Rota]], while casually browsing the mathematical stacks of [[Sterling Library]], stumbled upon a handwritten mailing list attached to Gibbs' s course notes. It listed over two hundred of the most notable scientists of Gibbs's time, including [[Henri Poincaré|Poincaré]], [[Hilbert]], [[Boltzmann]], and [[Mach]]. One must infer that Gibbs' work was somewhat better known among the scientific elite of his day than public material suggests. |
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⚫ | Gibbs' contributions, however, were not fully recognized until well after the 1923 publication of [[Gilbert N. Lewis]] and [[Merle Randall]]'s 1923 ''Thermodynamics and the Free Energy of Chemical Substances'', which introduced the methods of Gibbs to chemists world-wide. These methods became much of the foundation of the science of [[chemical engineering]]. |
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According to the [[American Mathematical Society]], which established the Josiah Willard Gibbs Lectureship in 1923 to increase public awareness of the aspects of [[mathematics]] and its applications, Gibbs is one of the greatest scientists America has ever produced.<ref>[http://www.ams.org/meetings/gibbs-lect.html Josiah Willard Gibbs Lectures] - [[American Mathematical Society]]</ref> |
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In 1945, Yale University created the [[J. Willard Gibbs Professorship in Theoretical Chemistry]], held until 1973 by [[Lars Onsager]], who won the 1968 Nobel Prize in chemistry. This appointment was a very fitting one, as Onsager, like Gibbs, was primarily involved in the application of new mathematical ideas to problems in physical chemistry, especially statistical mechanics. There is also a [http://www.mechanics.rutgers.edu/Vita.pdf J. Willard Gibbs Professorship of Thermomechanics] presently held by [[Bernard D. Coleman]] at [[Rutgers University]].<ref> |
In 1945, Yale University created the [[J. Willard Gibbs Professorship in Theoretical Chemistry]], held until 1973 by [[Lars Onsager]], who won the 1968 Nobel Prize in chemistry. This appointment was a very fitting one, as Onsager, like Gibbs, was primarily involved in the application of new mathematical ideas to problems in physical chemistry, especially statistical mechanics. There is also a [http://www.mechanics.rutgers.edu/Vita.pdf J. Willard Gibbs Professorship of Thermomechanics] presently held by [[Bernard D. Coleman]] at [[Rutgers University]].<ref> |
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[http://chmwww.rutgers.edu/~mbcenter/Faculty.html J. Willard Gibbs Professor of Thermomechanics |
[http://chmwww.rutgers.edu/~mbcenter/Faculty.html J. Willard Gibbs Professor of Thermomechanics |
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] - Rutgers University.</ref> |
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In 1950, Gibbs was elected to the [[Hall of Fame for Great Americans]]. |
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On February 28, 2003, Yale held a 100th anniversary symposium in his honor.<ref>[http://www.hssonline.org/profession/profession_frame.html?http://www.hssonline.org/action.lasso?-database=Guide_Events&-layout=web&nID=100749&-Search&-response=profession/meetings/detail.lasso J. Willard Gibbs and his Legacy: A Double Centennial] - Yale University (2003).</ref> |
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==Nobelists derived from the works of Gibbs== |
==Nobelists derived from the works of Gibbs== |
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The following individuals won a Nobel Prize in whole or in part by building on Gibbs's work: |
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In 1901, Gibbs was awarded the [[Copley Medal]] of the [[Royal Society]] of the [[United Kingdom]], illustrating worldwide recognition of his work among contemporary theoreticians. This medal, awarded to only one scientist each year, was the highest possible honor granted by the international scientific community of his day. |
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⚫ | Gibbs' contributions, however, were not fully recognized until well after the 1923 publication of [[Gilbert N. Lewis]] and [[Merle Randall]] |
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⚫ | *[[Max Planck]] of Germany won the 1918 [[Nobel prize in physics]] for his work in [[quantum mechanics]], particularly his 1900 [[History of quantum mechanics|quantum theory]] paper. This work is largely based on the thermodynamics of [[Rudolf Clausius]], Gibbs, and [[Ludwig Boltzmann]]. Nevertheless, Planck said about Gibbs: "…whose name not only in America but in the whole world will ever be reckoned among the most renowned theoretical physicists of all times…". |
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⚫ | *At the turn of the 20th century, [[Gilbert N. Lewis]] and [[Merle Randall]] used and extended Gibbs's work on [[chemical thermodynamic]], published their results in the 1923 textbook ''Thermodynamics and the Free Energy of Chemical Substances'', one of the two founding books in chemical thermodynamics. In the 1910s, [[William Giauque]] entered the College of Chemistry at Berkeley, where he received a bachelor of science degree in chemistry, with honors, in 1920. At first he wanted to become a [[chemical engineer]], but soon developed an interest in chemical research under Lewis's influence. In 1934, Giauque became a full Professor of Chemistry at Berkeley. In 1949, he won the [[Nobel Prize in Chemistry]] for his studies in the properties of matter at temperatures close to absolute zero, studies guided by the [[third law of thermodynamics]]. |
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⚫ | * Gibbs strongly influenced the education of the economist [[Irving Fisher]], who was awarded a Yale Ph.D. in economics in 1896. One of Gibbs's protegés was [[Edwin Bidwell Wilson]], who in turn passed his Gibbsian knowledge to the American [[economist]] [[Paul Samuelson]].<ref name="Samuelson" /> In 1947, Samuelson published ''[[Foundations of Economic Analysis]]'', based on his [[Harvard University]] doctoral dissertation. Samuelson explicitly acknowledged the influence of the [[chemical thermodynamics|classical thermodynamic]] methods of Gibbs.<ref>Liossatos, Panagis, S. (2004). "[http://www.fiu.edu/orgs/economics/wp2004/04-14.pdf Statistical Entropy in General Equilibrium Theory,]" (pg. 3). Department of Economics, Florida International University.</ref> Samuelson was the sole recipient of the [[Bank of Sweden Prize in Economic Sciences in Memory of Alfred Nobel|Nobel Prize in Economics]] in [[1970]], the second year of the Prize.<ref>[http://nobelprize.org/nobel_prizes/economics/laureates/1970/samuelson-lecture.html "Maximum Principles in Analytical Economics"], Nobel Prize Lecture</ref> In 2003, Samuelson described Gibbs as "[[Yale]]'s great physicist".<ref name="Samuelson"> [http://nobelprize.org/nobel_prizes/economics/articles/samuelson-2/index.html How I Became an Economist] by [[Paul A. Samuelson]], 1970 Laureate in Economics, 5 September 2003</ref> |
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⚫ | *At the turn of the 20th century, [[Gilbert N. Lewis]] |
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⚫ | * |
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==Tributes== |
==Tributes== |
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{{quote|…who founded a new department of chemical science which is becoming comparable in importance with that created by [[Lavoisier]].|[[Henri Louis Le Chatelier]], formulator of [[Le Chatelier's principle]] (1885)}} |
{{quote|…who founded a new department of chemical science which is becoming comparable in importance with that created by [[Lavoisier]].|[[Henri Louis Le Chatelier]], formulator of [[Le Chatelier's principle]] (1885)}} |
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{{quote|Willard Gibbs is, in my opinion, one of the most original and important creative minds in the field of science [[United States|America]] has produced.|[[Albert Einstein]], |
{{quote|Willard Gibbs is, in my opinion, one of the most original and important creative minds in the field of science [[United States|America]] has produced.|[[Albert Einstein]], physicist}} |
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{{quote|To [[physical chemistry]] he gave form and content for a hundred years.|[[Wilhelm Ostwald]], German chemist}} |
{{quote|To [[physical chemistry]] he gave form and content for a hundred years.|[[Wilhelm Ostwald]], German chemist}} |
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{{quote|Just as Newton first conclusively showed that this is a world of masses, so Willard Gibbs first revealed it as a world of systems.|[[Lawrence Joseph Henderson]], American biochemist in |
{{quote|Just as Newton first conclusively showed that this is a world of masses, so Willard Gibbs first revealed it as a world of systems.|[[Lawrence Joseph Henderson]], American biochemist in ''The Order of Nature'' (1917: 126)}} |
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{{quote|They laugh best who laugh last. Wait till we’re dead twenty years. Look at the way they’re treating poor Willard Gibbs, who during his lifetime can hardly have been considered any great shakes at [[New Haven]].|[[William James]], American psychologist and philosopher}} |
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{{quote|.. |
{{quote|They laugh best who laugh last. Wait till we're dead twenty years. Look at the way they're treating poor Willard Gibbs, who during his lifetime can hardly have been considered any great shakes at [[New Haven]].|[[William James]], American psychologist and philosopher}} |
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{{quote|...it was not Einstein or Planck or Heisenberg, but Willard Gibbs who brought on the first great revolution in twentieth century physics...|[[William Gaddis]], American Author}} |
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: [[Howard Scott]] leader of the [[Technical Alliance]] and later [[Technocracy Incorporated]] cited Gibbs as the intellectual scientific forefather of the concepts of [[Technocracy]].<ref>[http://www.technocracy.org/Archives/History%20&%20Purpose-r.htm History and Purpose of Technocracy by Howard Scott]</ref><ref>[http://www.technocracy.org/origins-1.htm The Origins of Technocracy. From the Technocracy Movement website - Scott's statement is on the video]</ref> |
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==Quotations== |
==Quotations== |
Revision as of 19:59, 4 June 2008
- For Josiah Willard Gibbs, Sr., see Willard Gibbs (linguist).
J. Willard Gibbs | |
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![]() (1839-1903) | |
Born | |
Died | April 28, 1903 | (aged 64)
Nationality | U.S. |
Alma mater | Yale University |
Known for | Gibbs free energy Gibbs entropy Vector analysis Gibbs-Helmholtz equation Gibbs algorithm Gibbs distribution Gibbs state Gibbs phenomenon |
Awards | Rumford Prize (1880) Copley Medal (1901) |
Scientific career | |
Fields | Physicist |
Institutions | Yale University |
Doctoral advisor | Gustav Kirchhoff Hermann von Helmholtz |
Doctoral students | Edwin Bidwell Wilson Irving Fisher |
Josiah Willard Gibbs (February 11, 1839 – April 28, 1903) was an American theoretical physicist and chemist, and mathematician. One of the greatest American scientists of all ime, he devised much of the theoretical foundation for chemical thermodynamics as well as physical chemistry. As a mathematician, he invented vector analysis (independently of Oliver Heaviside). It is in good part thanks to Gibbs that much of physical and chemical theory has since been exposited using vector analysis. Yale University awarded Gibbs the first American Ph.D. in engineering in 1863, and he spent his entire career at Yale.[1]
In 1901, Gibbs was awarded the highest possible honor granted by the international scientific community of his day, granted to only one scientist each year: the Copley Medal of the Royal Society of London, for being "the first to apply the second law of thermodynamics to the exhaustive discussion of the relation between chemical, electrical, and thermal energy and capacity for external work."[2] This quotation summarizes Gibbs's greatest scientific contribution.
Biography
Early years
![](http://upload.wikimedia.org/wikipedia/commons/thumb/a/a4/A_young_Willard_Gibbs.jpg/170px-A_young_Willard_Gibbs.jpg)
Gibbs was the seventh in a long line of American academics stretching back to the 17th century. His father, a professor of sacred literature at the Yale Divinity School, is now most remembered for his involvement in the Amistad trial. Although the father was also named Josiah Willard, the son is never referred to as "Jr." Five other members of Gibbs's extended family were named Josiah Willard Gibbs. His mother was the daughter of a Yale graduate in literature.
After attending the Hopkins School, Gibbs matriculated at Yale College at the age of 15. He graduated in 1858 near the top of his class, and was awarded prizes in mathematics and Latin.
Middle years
In 1863, Gibbs was awarded the first Ph.D. degree in engineering in the USA from the Sheffield Scientific School at Yale. He then tutored at Yale, two years in Latin and one year in what was then called natural philosophy, now comparable to the natural sciences, particularly physics. In 1866 he went to Europe to study, spending a year each at Paris, Berlin, and Heidelberg, where he was influenced by Kirchhoff and Helmholtz. At the time, German academics were the leading authorities in chemistry, thermodynamics, and theoretical natural science in general. These three years account for nearly all of his life spent outside New Haven.
In 1869, he returned to Yale and was appointed Professor of Mathematical Physics in 1871, the first such professorship in the United States and a position he held for the rest of his life. The appointment was unpaid at first, a situation common in Germany and otherwise not unusual at the time, because Gibbs had yet to publish anything. Between 1876 and 1878 Gibbs wrote a series of papers on the graphical analysis of multi-phase chemical systems. These were eventually published together in a monograph titled On the Equilibrium of Heterogeneous Substances, his most renowned work. It is now deemed one of the greatest scientific achievements of the 19th century, and one of the foundations of physical chemistry. In these papers Gibbs applied thermodynamics to interpret physicochemical phenomena, successfully explaining and interrelating what had previously been a mass of isolated facts.
"It is universally recognised that its publication was an event of the first importance in the history of chemistry. ... Nevertheless it was a number of years before its value was generally known, this delay was due largely to the fact that its mathematical form and rigorous deductive processes make it difficult reading for anyone, and especially so for students of experimental chemistry whom it most concerns... " (J J O'Connor and E F Robertson, J. Willard Gibbs)
Some important topics covered in his other papers on heterogeneous equilibria include:
- The concepts of chemical potential and free energy (available energy);
- A Gibbsian ensemble ideal, a foundation of statistical mechanics;
- The Gibbs phase rule.
![](http://upload.wikimedia.org/wikipedia/en/thumb/f/fc/Gibbs-plot.jpg/170px-Gibbs-plot.jpg)
Gibbs also wrote on theoretical thermodynamics. In 1873, he published a paper on the geometric representation of thermodynamic quantities. This paper inspired Maxwell to make (with his own hands) a plaster cast illustrating Gibbs's construct which he then sent to Gibbs. Yale proudly owns it to this day.
Later years
In 1880, the new Johns Hopkins University in Baltimore, Maryland offered Gibbs a position paying $3000. Yale responded by raising his salary to $2000, and he did not leave New Haven. From 1880 to 1884, Gibbs combined the ideas of two mathematicians, the quaternions of William Rowan Hamilton and the exterior algebra of Hermann Grassmann to obtain vector analysis (independently formulated by the British mathematical physicist and engineer Oliver Heaviside). Gibbs designed vector analysis to clarify and advance mathematical physics.
From 1882 to 1889, Gibbs refined his vector analysis, wrote on optics, and developed a new electrical theory of light. He deliberately avoided theorizing about the structure of matter (a wise decision, given the revolutionary developments in subatomic particles and quantum mechanics that began around the time of his death), developing a theory of greater generality than any other theory of matter extant in his day.
After 1889, he worked on statistical mechanics, laying a foundation and "providing a mathematical framework for quantum theory and for Maxwell's theories" [3] He wrote classic textbooks on statistical mechanics, which Yale published in 1902. Gibbs also contributed to crystallography and applied his vector methods to the determination of planetary and comet orbits.
Not much is known about the names and careers of Gibbs's students.
Gibbs never married, living all his life in his childhood home with a sister and his brother-in-law, the Yale librarian. His focus on science was such that he was generally unavailable personally. His protégé E.B. Wilson explains: "Except in the classroom I saw very little of Gibbs. He had a way, toward the end of the afternoon, of taking a stroll about the streets between his study in the old Sloane Laboratory and his home -- a little exercise between work and dinner -- and one might occasionally come across him at that time." Gibbs died in New Haven and is buried in Grove Street Cemetery.
Scientific recognition
Recognition was slow in coming, in part because Gibbs published mainly in the Transactions of the Connecticut Academy of Sciences, a journal edited by his librarian brother-in-law, little read in the USA and even less so in Europe. At first, only a few European theoretical physicists and chemists, such as the Scot James Clerk Maxwell, paid any attention to his work. Only when Gibbs's papers were translated into German (then the leading language for chemistry) by Wilhelm Ostwald in 1892, and into French by Henri Louis le Chatelier in 1899, did his ideas receive wide currency in Europe. His theory of the phase rule was experimentally validated by the works of H. W. Bakhuis Roozeboom, who showed how to apply it in a variety of situations, thereby assuring it of widespread use.
Gibbs was even less appreciated in his native America. Nevertheless, he was recognised as follows:
- In 1880, the American Academy of Arts and Sciences awarded Gibbs its Rumford Prize for his work in heat.[4]
- In 1910, the American Chemical Society, Chicago section, at the instigation of William A. Converse, established the Willard Gibbs Medal in his memory.[5]
During his lifetime, American colleges and secondary schools emphasized classics rather than science, and students took little interest in his Yale lectures. (That scientific teaching and research are a fundamental part of the modern university emerged in Germany during the 19th century and only gradually spread from there to the USA.) Gibbs's position at Yale and in American science generally has been described as follows:
"In his later years he was a tall, dignified gentleman, with a healthy stride and ruddy complexion, performing his share of household chores, approachable and kind (if unintelligible) to students. Gibbs was highly esteemed by his friends, but American science was too preoccupied with practical questions to make much use of his profound theoretical work during his lifetime. He lived out his quiet life at Yale, deeply admired by a few able students but making no immediate impress on American science commensurate with his genius." (Crowther 1969: nnn)
This is not to say that Gibbs was unknown in his day. For example, the mathematician Gian-Carlo Rota, while casually browsing the mathematical stacks of Sterling Library, stumbled upon a handwritten mailing list attached to Gibbs' s course notes. It listed over two hundred of the most notable scientists of Gibbs's time, including Poincaré, Hilbert, Boltzmann, and Mach. One must infer that Gibbs' work was somewhat better known among the scientific elite of his day than public material suggests.
Gibbs' contributions, however, were not fully recognized until well after the 1923 publication of Gilbert N. Lewis and Merle Randall's 1923 Thermodynamics and the Free Energy of Chemical Substances, which introduced the methods of Gibbs to chemists world-wide. These methods became much of the foundation of the science of chemical engineering.
According to the American Mathematical Society, which established the Josiah Willard Gibbs Lectureship in 1923 to increase public awareness of the aspects of mathematics and its applications, Gibbs is one of the greatest scientists America has ever produced.[6]
In 1945, Yale University created the J. Willard Gibbs Professorship in Theoretical Chemistry, held until 1973 by Lars Onsager, who won the 1968 Nobel Prize in chemistry. This appointment was a very fitting one, as Onsager, like Gibbs, was primarily involved in the application of new mathematical ideas to problems in physical chemistry, especially statistical mechanics. There is also a J. Willard Gibbs Professorship of Thermomechanics presently held by Bernard D. Coleman at Rutgers University.[7] Yale's J. W. Gibbs Laboratory and J. Willard Gibbs Assistant Professorship in Mathematics are also named in his honor.
In 1950, Gibbs was elected to the Hall of Fame for Great Americans.
On February 28, 2003, Yale held a 100th anniversary symposium in his honor.[8]
On May 4, 2005, the United States Postal Service issued the American Scientists commemorative postage stamp series, depicting Gibbs, John von Neumann, Barbara McClintock and Richard Feynman.
Nobelists derived from the works of Gibbs
The following individuals won a Nobel Prize in whole or in part by building on Gibbs's work:
- Johann van der Waals of the Netherlands won the 1910 Nobel prize in physics. In his Nobel Lecture, he acknowledged the influence on his work of Gibbs's equations of state.
- Max Planck of Germany won the 1918 Nobel prize in physics for his work in quantum mechanics, particularly his 1900 quantum theory paper. This work is largely based on the thermodynamics of Rudolf Clausius, Gibbs, and Ludwig Boltzmann. Nevertheless, Planck said about Gibbs: "…whose name not only in America but in the whole world will ever be reckoned among the most renowned theoretical physicists of all times…".
- At the turn of the 20th century, Gilbert N. Lewis and Merle Randall used and extended Gibbs's work on chemical thermodynamic, published their results in the 1923 textbook Thermodynamics and the Free Energy of Chemical Substances, one of the two founding books in chemical thermodynamics. In the 1910s, William Giauque entered the College of Chemistry at Berkeley, where he received a bachelor of science degree in chemistry, with honors, in 1920. At first he wanted to become a chemical engineer, but soon developed an interest in chemical research under Lewis's influence. In 1934, Giauque became a full Professor of Chemistry at Berkeley. In 1949, he won the Nobel Prize in Chemistry for his studies in the properties of matter at temperatures close to absolute zero, studies guided by the third law of thermodynamics.
- Gibbs strongly influenced the education of the economist Irving Fisher, who was awarded a Yale Ph.D. in economics in 1896. One of Gibbs's protegés was Edwin Bidwell Wilson, who in turn passed his Gibbsian knowledge to the American economist Paul Samuelson.[9] In 1947, Samuelson published Foundations of Economic Analysis, based on his Harvard University doctoral dissertation. Samuelson explicitly acknowledged the influence of the classical thermodynamic methods of Gibbs.[10] Samuelson was the sole recipient of the Nobel Prize in Economics in 1970, the second year of the Prize.[11] In 2003, Samuelson described Gibbs as "Yale's great physicist".[9]
Tributes
The greatest thermodynamicist of them all
…who founded a new department of chemical science which is becoming comparable in importance with that created by Lavoisier.
— Henri Louis Le Chatelier, formulator of Le Chatelier's principle (1885)
Willard Gibbs is, in my opinion, one of the most original and important creative minds in the field of science America has produced.
— Albert Einstein, physicist
To physical chemistry he gave form and content for a hundred years.
— Wilhelm Ostwald, German chemist
Just as Newton first conclusively showed that this is a world of masses, so Willard Gibbs first revealed it as a world of systems.
— Lawrence Joseph Henderson, American biochemist in The Order of Nature (1917: 126)
Gibbs Phase Rule, a general theorem of thermodynamics which is so fundamental that it is unlikely ever to be overthrown
They laugh best who laugh last. Wait till we're dead twenty years. Look at the way they're treating poor Willard Gibbs, who during his lifetime can hardly have been considered any great shakes at New Haven.
— William James, American psychologist and philosopher
...it was not Einstein or Planck or Heisenberg, but Willard Gibbs who brought on the first great revolution in twentieth century physics...
— William Gaddis, American Author
Quotations
- "Mathematics is a language." (reportedly spoken by Gibbs at a Yale faculty meeting)
- "A mathematician may say anything he pleases, but a physicist must be at least partially sane."
- "It has been said that 'the human mind has never invented a labor-saving machine equal to algebra.' If this be true, it is but natural and proper that an age like our own, characterized by the multiplication of labor-saving machinery, should be distinguished by the unexampled development of this most refined and most beautiful of machines." (1887, quoted in Meinke and Tucker 1992: 190)
See also
- Science: Information theory, Information entropy
- Electricity: Maxwell's equations
- Mathematics: Gibbs phenomenon, Vector Analysis (Gibbs/Wilson), cross product
- Physical chemistry: Matter phase, Gibbs phase rule, Statistical mechanics, Free energy
- Named for Gibbs: Gibbs free energy, Gibbs entropy, Gibbs inequality, Gibbs paradox, Gibbs-Helmholtz equation, Gibbs algorithm, Gibbs distribution, Gibbs state, Gibbs sampling, Gibbs-Marangoni effect, Gibbs-Duhem relation, Gibbs phenomenon, Gibbs-Donnan effect
- People: Gilbert N. Lewis, William Rowan Hamilton, Lars Onsager, Ludwig Boltzmann, William Stanley, Oliver Heaviside
- Other: Copley Medal, Yale University, Grove Street Cemetery
- Lists: List of physicists, Timeline of thermodynamics, List of physics topics, List of notable textbooks in statistical mechanics
References
- ^ Wheeler, Lynde, Phelps (1951). Josiah Willard Gibbs - the History of a Great Mind. Ox Bow Press. ISBN 1-881987-11-6.
{{cite book}}
: CS1 maint: multiple names: authors list (link) - ^ Josiah Willard Gibbs - Britannica 1911
- ^ J. J. O'Connor and E. F. Robertson, "J. Willard Gibbs".
- ^ Müller, Ingo (2007). A History of Thermodynamics - the Doctrine of Energy and Entropy. Springer. ISBN 978-3-540-46226-2.
- ^ Willard Gibbs Medal - Founded by William A. Converse in 1910
- ^ Josiah Willard Gibbs Lectures - American Mathematical Society
- ^ [http://chmwww.rutgers.edu/~mbcenter/Faculty.html J. Willard Gibbs Professor of Thermomechanics ] - Rutgers University.
- ^ J. Willard Gibbs and his Legacy: A Double Centennial - Yale University (2003).
- ^ a b How I Became an Economist by Paul A. Samuelson, 1970 Laureate in Economics, 5 September 2003
- ^ Liossatos, Panagis, S. (2004). "Statistical Entropy in General Equilibrium Theory," (pg. 3). Department of Economics, Florida International University.
- ^ "Maximum Principles in Analytical Economics", Nobel Prize Lecture
- ^ Fenn, John, B. (1982). Engines, Energy, and Entropy – a Thermodynamics Primer. W.H. Freeman and Co. ISBN 0-7167-1281-4.
{{cite book}}
: CS1 maint: multiple names: authors list (link)
Further reading
Primary:
- 1947. The Early Work of Willard Gibbs in Applied Mechanics, New York, Henry Schuman
- 1961. Scientific Papers of J Willard Gibbs, 2 vols. Bumstead, H. A., and Van Name, R. G., eds. ISBN 0918024773
- Elementary Principles in Statistical Mechanics.
Secondary :
- Online bibliography.
- American Institute of Physics, 2003 (1976). Josiah Willard Gibbs
- Bumstead, H. A., 1903. "Josiah Willard Gibbs" American Journal of Science XVI(4).
- Crowther, J. G., 1969. Famous American Men of Science. ISBN 0836900405
- Donnan, F. G., Haas, A. E., and Duhem, P. M. M., 1936. A Commentary on the Scientific Writings of J Willard Gibbs. ISBN 0405125445
- Hastings, Charles S. ,1909. Josiah Willard Gibbs. Biographical Memoirs of the National Academy of Sciences 6:372–393.
- Longley, W. R., and R. G. Van Name, eds., 1928. The Collected Works of J Willard Gibbs.
- Meinke, K., and Tucker, J. V., 1992, "Universal Algebra" in Abramsky, S., Gabbay, D., and Maibaum, T. S. E., eds., Handbook of Logic in Computer Science: Vol. I. Oxford Univ. Press: 189-411. ISBN 0198537611
- Muriel Rukeyser, 1942. Willard Gibbs: American Genius. Woodbridge, CT: Ox Bow Press. ISBN 0918024579.
- Seeger, Raymond John, 1974. J. Willard Gibbs, American mathematical physicist par excellence. Pergamon Press. ISBN 0080180132
- Wheeler, L. P., 1952. Josiah Willard Gibbs, The History of a Great Mind. ISBN 1881987116
- Edwin Bidwell Wilson (1931) "Reminiscences of Gibbs by a student and colleague", Scientific Monthly 32:211-27.
External links
- O'Connor, John J.; Robertson, Edmund F., "Josiah Willard Gibbs", MacTutor History of Mathematics Archive, University of St Andrews
- Friel, Charles Michael, "J. Willard Gibbs".
- Jolls, Kenneth R., and Daniel C. Coy, "Gibbs models". Iowa State University.
- 1839 births
- 1903 deaths
- Thermodynamicists
- Theoretical physicists
- Mathematical analysts
- American chemists
- American physicists
- American mathematicians
- 19th century mathematicians
- Yale University alumni
- University of Heidelberg alumni
- Yale University faculty
- Hopkins School alumni
- People from New Haven, Connecticut
- Recipients of the Copley Medal
- Burials at Grove Street Cemetery