Ernst Chladni

Ernst Chladni
Ernst Chladni
Born 30 November 1756
Wittenberg, Electorate of Saxony in the Holy Roman Empire
Died 3 April 1827 (1827-04-04) (aged 70)
Breslau, Province of Silesia in the Kingdom of Prussia, a part of the German Confederation
Nationality German
Known for
Scientific career
Fields Physics

Ernst Florens Friedrich Chladni (German: [ˈɛʁnst ˈfloːʁɛns ˈfʁiːdʁɪç ˈkladnɪ]; 30 November 1756 – 3 April 1827) was a German physicist and musician. His most important work, for which he is sometimes labeled the father of acoustics, included research on vibrating plates and the calculation of the speed of sound for different gases.[1] He also undertook pioneering work in the study of meteorites and is regarded by some as the father of meteoritics.[2]

Early life

Although Chladni was born in Wittenberg in Saxony, his family originated from Kremnica, then part of the Kingdom of Hungary and today a mining town in central Slovakia. Chladni has therefore been identified as German,[3][4] Hungarian[5] and Slovak.[6]

Martin Chladni, Ernst Chladni's grandfather

Chladni came from an educated family of academics and learned men. Chladni's great-grandfather, the Lutheran clergyman Georg Chladni (1637–92), had left Kremnica in 1673 during the Counter Reformation. Chladni's grandfather, Martin Chladni (1669–1725), was also a Lutheran theologian and, in 1710, became professor of theology at the University of Wittenberg. He was dean of the theology faculty in 1720–1721 and later became the university's rector. Chladni's uncle, Justus Georg Chladni (1701–1765), was a law professor at the university. Another uncle, Johann Martin Chladni (1710–1759), was a theologian, a historian and a professor at the University of Erlangen and the University of Leipzig.

Chladni's method of creating Chladni figures

Chladni's father, Ernst Martin Chladni (1715–1782), was a law professor and rector of the University of Wittenberg. He had joined the law faculty there in 1746. Chladni's mother was Johanna Sophia and he was an only child.[7] His father disapproved of his son's interest in science and insisted that Chladni become a lawyer.[6][8][9]

Career

Chladni studied law and philosophy in Wittenberg and Leipzig, obtaining a law degree from the University of Leipzig in 1782. That same year, his father died and he turned to physics in earnest.[8][9]

Chladni figures

Chladni patterns of a guitar backplate
Chladni figure on a rectangular plate supported in center
Another mode of the same plate

One of Chladni's best-known achievements was inventing a technique to show the various modes of vibration on a rigid surface. When resonating, a plate or membrane is divided into regions that vibrate in opposite directions, bounded by lines where no vibration occurs (nodal lines). Chladni repeated the pioneering experiments of Robert Hooke who, on July 8, 1680, had observed the nodal patterns associated with the vibrations of glass plates. Hooke ran a violin bow along the edge of a plate covered with flour and saw the nodal patterns emerge.[8][9]

Chladni's technique, first published in 1787 in his book Entdeckungen über die Theorie des Klanges ("Discoveries in the Theory of Sound"), consisted of drawing a bow over a piece of metal whose surface was lightly covered with sand. The plate was bowed until it reached resonance, when the vibration causes the sand to move and concentrate along the nodal lines where the surface is still, outlining the nodal lines. The patterns formed by these lines are what are now called Chladni figures. Similar nodal patterns can also be found by assembling microscale materials on Faraday waves.[10]

When Chladni showed the technique in Paris, Napoleon set a prize for the best mathematical explanation. Sophie Germain's answer, although rejected due to flaws, was the only entry with the correct approach.[11]

Variations of this technique are still commonly used in the design and construction of acoustic instruments such as violins, guitars, and cellos. Since the 20th century, it has become more common to place a loudspeaker driven by an electronic signal generator over or under the plate to achieve a more accurate adjustable frequency.

In quantum mechanics, Chladni figures ("nodal patterns") are known to be related to the solutions of the Schrödinger equation for one-electron atoms, and the mathematics describing them was used by Erwin Schrödinger to arrive at the understanding of electron orbitals.[12]

Chladni figures

Musical instruments

Since at least 1738, a musical instrument called a Glasspiel or verrillon, created by filling beer glasses with varying amounts of water, was popular in Europe.[13] The beer glasses were struck by wooden mallets shaped like spoons to produce "church and other solemn music".[14] Benjamin Franklin was sufficiently impressed by a verrillon performance on a visit to London in 1757 that he created his own instrument, the glass armonica, in 1762. Franklin's armonica inspired several other instruments, including two created by Chladni. In 1791, Chladni invented the musical instrument called the euphon (not to be confused with the brass instrument euphonium), consisting of glass rods of different pitches. Chladni's euphon is the direct ancestor of the modern day musical instrument known as the Cristal Baschet.[15] Chladni also improved on Hooke's "musical cylinder" to produce another instrument, the clavicylinder, in 1799.[8][9][14]

Chladni travelled throughout Europe with his instruments giving demonstrations.[6]

Instruments - Chladni

Meteorites

In 1794, Chladni published Über den Ursprung der von Pallas gefundenen und anderer ihr ähnlicher Eisenmassen und über einige damit in Verbindung stehende Naturerscheinungen ("On the Origin of the Iron Masses Found by Pallas and Others Similar to it, and on Some Associated Natural Phenomena") in which he proposed that meteorites have an extraterrestrial origin.[16][17] This was a controversial statement at the time,[18] since meteorites were thought to be of volcanic origin. This book made Chladni one of the founders of modern meteorite research.

Chladni was initially ridiculed for his claims, but his writings sparked a curiosity that eventually led more researchers supporting his theory. In 1795, a large stony meteorite was observed during its fall to Earth at a cottage near Wold Newton in Yorkshire, England and a piece of it, known as the Wold Cottage meteorite, was given to the British chemist Edward Howard who, along with French mineralogist Jacques de Bournon, carefully analyzed its composition and concluded that an extraterrestrial origin was likely.[19] In 1803, the physicist and astronomer Jean Baptiste Biot was commissioned by the French Minister of the Interior to investigate a meteor shower over L'Aigle in northern France that had peppered the town with thousands of meteorite fragments.[20][8][9] Unlike Chladni's book and the scientific publication by Howard and de Bournon, Biot's lively report became popular and persuaded more people to take Chladni's insights seriously.[17]

A mineral, first described in 1993 from the Carlton (IIICD) iron meteorite, was named chladniite in his honor.[2][21]

Other work

Chladni discovered Chladni's law, a simple algebraic relation for approximating the modal frequencies of the free oscillations of plates and other bodies.[22]

Chladni estimated sound velocities in different gases by placing those gases in an organ pipe and measuring the characteristics of the sounds that emerged when the pipe was played.[23] This built on work on measuring the speed of sound in air that Pierre Gassendi began in 1635.

Death

Chladni died on April 3, 1827, in Breslau, Lower Silesia, then part of the Kingdom of Prussia and today the city of Wrocław in southwestern Poland.[24]

Bibliography

  • Entdeckungen über die Theorie des Klanges, Leipzig 1787.
  • Die Akustik, Leipzig 1802. French translation: Traite d’acoustique, Paris 1809. Also in Neue Beiträge zur Akustik, Leipzig 1817.
  • Beiträge zur praktischen Akustik und zur Lehre vom Instrumentbau, Leipzig 1821 ( OCLC 457664981).
  • Über den Ursprung der von Pallas gefundenen und anderer ihr ähnlicher Eisenmassen at the HathiTrust, Leipzig/Riga 1794.
  • Über Feuermeteore, Vienna 1820.
  • Über die Hervorbringung der menschlichen Sprachlaute, Leipzig 1824.
  • Kurze Übersicht der Schall und Klanglehre, nebst einem Anhange die Entwickelung und Anordnung der Tonverhältnisse betreffend, Mainz 1827.

See also

References

  1. "Whipple Collections: Ernst Chladni". University of Cambridge. Retrieved 2010-02-27.
  2. 1 2 McCoy, T. J.; Steele, I. M.; Keil, K.; Leonard, B. F.; Endress, M.; Steele; Keil; Leonard; Endress (1993). "Chladniite: A New Mineral Honoring the Father of Meteoritics". Meteoritics. 28 (3): 394. Bibcode:1993Metic..28Q.394M.
  3. "Ernst Florens Friedrich Chladni, or Ernst F. F. Chladni (German physicist)", Encyclopædia Britannica: Related Articles
  4. Ernst Florens Friedrich Chladni, German physicist, 1802 Image Preview, Science and Society Picture Library
  5. McLaughlin, Joyce (1998). "Good Vibrations". American Scientist. 86 (4): 342. Bibcode:1998AmSci..86..342M. doi:10.1511/1998.4.342. Archived from the original on 2008-01-23. Retrieved 2007-11-02.
  6. 1 2 3 "Life and work of E.F.F. Chladni", D. Ullmann1, The European Physical Journal – Special Topics, Springer, Berlin / Heidelberg, ISSN 1951-6355 (Print) ISSN 1951-6401 (Online), Issue Volume 145, Number 1, June 2007, doi:10.1140/epjst/e2007-00145-4, pp. 25–32
  7. Hockey, Thomas (2009). The Biographical Encyclopedia of Astronomers. Springer Publishing. ISBN 978-0-387-31022-0. Retrieved August 22, 2012.
  8. 1 2 3 4 5 Daniel P McVeigh (2000). "Ernst Florens Friedrich Chladni". An Early History of the Telephone 1664-1865. Archived from the original on 2013-03-07.
  9. 1 2 3 4 5 P. 101 Oxford Dictionary of Scientists – Oxford University Press – 1999
  10. P. Chen, Z. Luo, S. Guven, S. Tasoglu, A. Weng, A. V. Ganesan, U. Demirci, Advanced Materials 2014, 10.1002/adma.201402079. http://onlinelibrary.wiley.com/doi/10.1002/adma.201402079/abstract
  11. "Revolutionary Mathematician". San Diego Supercomputer Center. Retrieved 16 March 2016.
  12. J. Michael McBride, "Chladni Figures and One-Electron Atoms", Lecture #9, Freshman Organic Chemistry (CHEM 125) course, Open Yale Courses, Yale University, video recorded Fall 2008, accessed on YouTube, https://www.youtube.com/watch?v=5kYLE8GhAuE, 2016-06-05.
  13. The 1911 edition of the Encyclopædia Britannica credits Edward Delaval with inventing the verrillon.
  14. 1 2 "Harmonica", Encyclopædia Britannica, Eleventh edition, 1911.
  15. "Les Sculptures Sonores: The Sound Sculptures of Bernard and Francois Baschet" by Francois Baschet, Author(s) of Review: Rahma Khazam, Leonardo, Vol. 33, No. 4 (2000), pp. 336–337
  16. Chladni, Ernst Florens Friedrich, Über den Ursprung der von Pallas gefundenen und anderer ihr ähnlicher Eisenmassen und über einige damit in Verbindung stehende Naturerscheinungen [On the origin of the iron masses found by Pallas and others similar to it, and on some natural phenomena associated with them] (Riga, Latvia: Johann Friedrich Hartknoch, 1794). Available on-line at: Saxon State and University Library at Dresden, Germany.
  17. 1 2 McSween, Harry Y. (1999). Meteorites and Their Parent Planets (2. ed.). Cambridge [u.a.]: Cambridge University Press. ISBN 0-521-58303-9.
  18. Williams, Henry Smith (1904). "5". A History of Science. 3. Harper. p. 168ff. ISBN 0-250-40142-8.
  19. Howard, Edward (1802). "Experiments and observations on certain stony and metalline substances, which at different times are said to have fallen on the Earth; also on various kinds of native iron". Philosophical Transactions of the Royal Society of London. 92: 168–212. Bibcode:1802RSPT...92..168H. doi:10.1098/rstl.1802.0009.
  20. See:
    • Biot, J.-B. (1803). "Relation d'un voyage fait dans le département de l'Orne pour constater la réalité d'un météore observé à l'Aigle le 6 floréal an XI" [Account of a trip made in the department of Orne to note the reality of a meteor observed at l'Aigle on 6 Floréal year XI]. Mémoires de la classe des sciences mathématiques et physiques de l'Institut National de France (in French). 7: 224–265.
    • Reprinted as a pamphlet: Biot, J.-B. (1803). Relation d’un voyage fait dans le département de l’Orne pour constater la réalité d’un météore observé à l’Aigle le 6 floréal an XI [Account of a trip made in the department of Orne to note the reality of a meteor observed at l'Aigle on 6 Floréal year XI] (in French). Paris, France: Baudoin.
  21. McCoy, T.J.; Steele, I.M.; Keil, K.; Leonard, B.F.; Endreβ, M. (1994). "Chladniite, Na2CaMg7(PO4)6: A new mineral from the Carlton (IIICD) iron meteorite". American Mineralogist. 79: 375–380. Bibcode:1994AmMin..79..375M.
  22. Kverno, Derek; Nolen, Jim. "History of Chladni's Law". Davidson College Physics Department. Retrieved 2018-04-02.
  23. Chladni, Ernst (1756–1827), Eric Weisstein's World of Scientific Biography.
  24. Musielak, Dora E. (23 January 2015). Prime Mystery: The Life and Mathematics of Sophie Germain. AuthorHouse. p. 52. ISBN 9781496965011. Retrieved 1 April 2018.

Further reading

  • Jackson, Myles W. (2006) Harmonious Triads: Physicists, Musicians, and Instrument Makers in Nineteenth-Century Germany (MIT Press).
  • Marvin, Ursula B. (1996). "Ernst florens Friedrich Chladni (1756–1827) and the origins of modern meteorite research". Meteoritics. 31 (5): 545–588. Bibcode:1996M&PS...31..545M. doi:10.1111/j.1945-5100.1996.tb02031.x.
  • Rossing T. D. (1982) Chladni's Law for Vibrating Plates, American Journal of Physics 50, 271–274
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