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Gabriel Lippmann

January 01, 1970

Jonas Ferdinand Gabriel Lippmann (16 August 1845 – 13 July 1921) was a Franco-Luxembourgish physicist and inventor, and Nobel laureate in physics for his method of reproducing colours photographically based on the phenomenon of interference.[2] His parents were French Jews.

Gabriel Lippmann
Lippmann in 1908
Born
Jonas Ferdinand Gabriel Lippmann

(1845-08-16)16 August 1845
Bonnevoie/Bouneweg, Luxembourg (since 1921 part of Luxembourg City)
Died13 July 1921(1921-07-13) (aged 75)
SS France, Atlantic Ocean
NationalityFrench
Alma materÉcole Normale Supérieure
Known for
AwardsNobel Prize for Physics (1908)
Scientific career
FieldsPhysics
InstitutionsSorbonne
Doctoral advisorGustav Kirchhoff
Other academic advisorsHermann von Helmholtz[1]
Doctoral studentsMarie Curie

Early life and education edit

Gabriel Lippmann was born in Bonnevoie, Luxembourg (Luxembourgish: Bouneweg), on 16 August 1845.[3] At the time, Bonnevoie was part of the commune of Hollerich (Luxembourgish: Hollerech), which is often given as his place of birth. (Both places, Bonnevoie and Hollerich, are now districts of Luxembourg City.) His father, Isaïe, a French Jew born in Ennery near Metz, managed the family glove-making business at the former convent in Bonnevoie. In 1848, the family moved to Paris, where Lippmann was initially tutored by his mother, Miriam Rose (Lévy), before attending the Lycée Napoléon (now Lycée Henri-IV).[4] He was said to have been a rather inattentive but thoughtful pupil with a special interest in mathematics. In 1868, he was admitted to the École normale supérieure in Paris, where he failed the agrégation examination which would have enabled him to enter the teaching profession, preferring instead to study physics. In 1872, the French government sent him on a mission to Heidelberg University, where he was able to specialize in electricity with the encouragement of Gustav Kirchhoff, receiving a doctorate with "summa cum laude" distinction in 1874.[5] Lippmann then returned to Paris in 1875, where he continued to study until 1878, when he became professor of physics at the Sorbonne.[6][7][8] At the Sorbonne he was teaching acoustics and optics.[9]

 
Professor Lippmann in the Sorbonne laboratory for research in physics (Bibliothèque de la Sorbonne, NuBIS)

Career edit

Lippmann made several important contributions to various branches of physics over the years.

 
Lippmann's electrometer (1872)

The capillary electrometer edit

One of Lippmann's early discoveries was the relationship between electrical and capillary phenomena, which allowed him to develop a sensitive capillary electrometer, subsequently known as the Lippmann electrometer which was used in the first ECG machine. In a paper delivered to the Philosophical Society of Glasgow on 17 January 1883, John G. M'Kendrick described the apparatus as follows:

Lippmann's electrometer consists of a tube of ordinary glass, 1 metre long and 7 millimetres in diameter, open at both ends, and kept in the vertical position by a stout support. The lower end is drawn into a capillary point, until the diameter of the capillary is .005 of a millimetre. The tube is filled with mercury, and the capillary point is immersed in dilute sulphuric acid (1 to 6 of water in volume), and in the bottom of the vessel containing the acid there is a little more mercury. A platinum wire is put into connection with the mercury in each tube, and, finally, arrangements are made by which the capillary point can be seen with a microscope magnifying 250 diameters. Such an instrument is very sensitive; and Lippmann states that it is possible to determine a difference of potential so small as that of one 10,080th of a Daniell. It is thus a very delicate means of observing and (as it can be graduated by a compensation-method) of measuring minute electromotive forces.[10][11]

Lippmann's PhD thesis, presented to the Sorbonne on 24 July 1875, was on electrocapillarity.[12]

Piezoelectricity edit

In 1881, Lippmann predicted the converse piezoelectric effect.[13]

Colour photography edit

 
A colour photograph made by Lippmann in the 1890s. It contains no pigments or dyes of any kind.

Above all, Lippmann is remembered as the inventor of a method for reproducing colours by photography, based on the interference phenomenon, which earned him the Nobel Prize in Physics for 1908.[7]

In 1886, Lippmann's interest turned to a method of fixing the colours of the solar spectrum on a photographic plate. On 2 February 1891, he announced to the Academy of Sciences: "I have succeeded in obtaining the image of the spectrum with its colours on a photographic plate whereby the image remains fixed and can remain in daylight without deterioration."[3] By April 1892, he was able to report that he had succeeded in producing colour images of a stained glass window, a group of flags, a bowl of oranges topped by a red poppy and a multicoloured parrot. He presented his theory of colour photography using the interference method in two papers to the Academy, one in 1894, the other in 1906.[5]

 
A standing wave. The red dots are the wave nodes.

The interference phenomenon in optics occurs as a result of the wave propagation of light. When light of a given wavelength is reflected back upon itself by a mirror, standing waves are generated, much as the ripples resulting from a stone dropped into still water create standing waves when reflected back by a surface such as the wall of a pool. In the case of ordinary incoherent light, the standing waves are distinct only within a microscopically thin volume of space next to the reflecting surface.

Lippmann made use of this phenomenon by projecting an image onto a special photographic plate capable of recording detail smaller than the wavelengths of visible light. The light passed through the supporting glass sheet into a very thin and nearly transparent photographic emulsion containing sub microscopically small silver halide grains. A temporary mirror of liquid mercury in intimate contact with the emulsion reflected the light back through it, creating standing waves whose nodes had little effect while their antinodes created a latent image. After development, the result was a structure of lamellae, a very fine fringe pattern in distinct parallel layers composed of submicroscopic metallic silver grains, which was a permanent record of the standing waves. Throughout the emulsion, the spacing of the lamellae corresponded to the half-wavelengths of the light photographed; λ/(2n), λ being the wavelength of light in air and n is the refractive index of the emulsion. Thus colour information was stored locally. The larger the separation between the fringes, the longer was the wavelength recorded from the image colour, red being the longest.[9]

The finished plate was illuminated from the front at a nearly perpendicular angle, using daylight or another source of white light containing the full range of wavelengths in the visible spectrum. At each point on the plate, light of approximately the same wavelength as the light which had generated the lamellae was strongly reflected back toward the viewer. Light of other wavelengths which was not absorbed or scattered by the silver grains simply passed through the emulsion, usually to be absorbed by a black anti-reflection coating applied to the back of the plate after it had been developed. The wavelengths, and therefore the colours, of the light which had formed the original image were thus reconstituted and a full-colour image was seen.[14][15][16]

In practice, the Lippmann process was not easy to use. Extremely fine-grained high-resolution photographic emulsions are inherently much less light-sensitive than ordinary emulsions, so long exposure times were required. With a lens of large aperture and a very brightly sunlit subject, a camera exposure of less than one minute was sometimes possible, but exposures measured in minutes were typical. Pure spectral colours reproduced brilliantly, but the ill-defined broad bands of wavelengths reflected by real-world objects could be problematic. The process did not produce colour prints on paper and it proved impossible to make a good duplicate of a Lippmann colour photograph by rephotographing it, so each image was unique. A very shallow-angled prism was usually cemented to the front of the finished plate to deflect unwanted surface reflections, and this made plates of any substantial size impractical. The size of his early photographs was 4 cm by 4 cm, increased later to 6.5 cm by 9 cm.[9] The lighting and viewing arrangement required to see the colours to best effect precluded casual use. Although the special plates and a plate holder with a built-in mercury reservoir were commercially available for a few years c. 1900, even expert users found consistent good results elusive and the process never graduated from being a scientifically elegant laboratory curiosity. It did, however, stimulate interest in the further development of colour photography.[16]

Lippmann's process foreshadowed laser holography, which is also based on recording standing waves in a photographic medium. Denisyuk reflection holograms, often referred to as Lippmann-Bragg holograms, have similar lamellar structures that preferentially reflect certain wavelengths. In the case of actual multiple-wavelength colour holograms of this type, the colour information is recorded and reproduced just as in the Lippmann process, except that the highly coherent laser light passing through the recording medium and reflected back from the subject generates the required distinct standing waves throughout a relatively large volume of space, eliminating the need for reflection to occur immediately adjacent to the recording medium. Unlike Lippmann colour photography, however, the lasers, the subject and the recording medium must all be kept stable to within one quarter of a wavelength during the exposure in order for the standing waves to be recorded adequately or at all.

Integral photography edit

In 1908, Lippmann introduced what he called "integral photography", in which a plane array of closely spaced, small, spherical lenses is used to photograph a scene, recording images of the scene as it appears from many slightly different horizontal and vertical locations. When the resulting images are rectified and viewed through a similar array of lenses, a single integrated image, composed of small portions of all the images, is seen by each eye. The position of the eye determines which parts of the small images it sees. The effect is that the visual geometry of the original scene is reconstructed, so that the limits of the array seem to be the edges of a window through which the scene appears life-size and in three dimensions, realistically exhibiting parallax and perspective shift with any change in the position of the observer.[17] This principle of using numerous lenses or imaging apertures to record what was later termed a light field underlies the evolving technology of light-field cameras and microscopes.

When Lippmann presented the theoretical foundations of his "integral photography" in March 1908, it was impossible to accompany them with concrete results. At the time, the materials necessary for producing a lenticular screen with the proper optical qualities were lacking. In the 1920s, promising trials were made by Eugène Estanave, using glass Stanhope lenses, and by Louis Lumière, using celluloid.[18] Lippmann's integral photography was the foundation of research on 3D and animated lenticular imagery and also on color lenticular processes.

Measurement of time edit

In 1895, Lippmann evolved a method of eliminating the personal equation in measurements of time, using photographic registration, and he studied the eradication of irregularities of pendulum clocks, devising a method of comparing the times of oscillation of two pendulums of nearly equal period.[4]

The coelostat edit

Lippmann also invented the coelostat, an astronomical tool that compensated for the Earth's rotation and allowed a region of the sky to be photographed without apparent movement.[4]

Brownian ratchet edit

In 1900, he proposed what is later called the Brownian ratchet, as a purely mechanical version of Maxwell's demon, purportedly showing that the kinetic theory of gas is incompatible with the second law of thermodynamics.[19][20]

Academic affiliations edit

Lippmann was a member of the Academy of Sciences from 8 February 1886 until his death, serving as its president in 1912.[21] In addition, he was a Foreign Member of the Royal Society of London, a member of the Bureau des Longitudes,[4] and a member of the Grand Ducal Institute of Luxembourg. He became a member of the Société française de photographie in 1892 and its president from 1896 to 1899.[22] Lippmann was one of the founders of the Institut d'optique théorique et appliquée in France. Lippmann was the President of the Société Astronomique de France (SAF), the French astronomical society, from 1903–1904.[23]

Honours edit

Lippmann was appointed a Knight of the Legion of Honour on 29 December 1881, promoted to Officer on 2 April 1894, to Commander on 14 December 1900, and to the dignity of Grand Officer on 6 December 1919.[24]

In Luxembourg City an Institute for fundamental scientific research was named after Lippmann (Centre de Recherche Public Gabriel Lippmann) which merged on 1 January 2015 with another major research centre to form the new Luxembourg Institute for Science and Technology (LIST).[25]

Personal life edit

Lippmann married the daughter of the novelist Victor Cherbuliez in 1888.[4] He died on 13 July 1921 aboard the steamer France while en route from Canada.[26]

See also edit

References edit

  1. ^ "Gabriel Lippmann". Mathematics Genealogy Project. Retrieved 31 August 2015.
  2. ^ "Gabriel Lippmann | French physicist". 12 August 2023.
  3. ^ a b Gabriel Lippmann's colour photography : science, media, museums. Hanin Hannouch. Amsterdam. 2022. ISBN 978-94-6372-855-3. OCLC 1304814408.{{cite book}}: CS1 maint: location missing publisher (link) CS1 maint: others (link)
  4. ^ a b c d e "Gabriel Lippmann". Nobel Foundation. from the original on 5 April 2016. Retrieved 4 December 2010.
  5. ^ a b Jacques Bintz, "Gabriel Lippmann 1845–1921", in Gabriel Lippmann: Commémoration par la section des sciences naturelles, physiques et mathématiques de l’Institut grand-ducal de Luxembourg du 150e anniversaire du savant né au Luxembourg, lauréat du prix Nobel en 1908 (Luxembourg: Section des sciences naturelles, physiques et mathématiques de l’Institut grand-ducal de Luxembourg en collaboration avec le Séminaire de mathématique et le Séminaire d’histoire des sciences et de la médecine du centre universitaire de Luxembourg, 1997), Jean-Paul Pier & Jos. A. Massard: éditeurs, Luxembourg 1997. Retrieved 4 December 2010.
  6. ^ Josef Maria Eder, History of Photography, 4th ed. (New York: Dover, 1978; ISBN 0-486-23586-6), p. 668. (This Dover edition reproduces the Columbia University Press edition of 1945; the book was originally published in 1932 as Geschichte der Photographie.)
  7. ^ a b From Nobel Lectures, Physics 1901–1921, Elsevier Publishing Company, Amsterdam, 1967
  8. ^ See also the extensive biography on The Nobel Prize in Physics 1908 page.
  9. ^ a b c Bjelkhagen, Hans I. (2008). "Lippmann, Gabriel Jonas (1845–1921) French scientist and physicist". In Hannavy, John (ed.). Encyclopedia of nineteenth-century photography (1st ed.). New York, NY: Routledge. pp. 132, 320, 647, 808, 862–3, 990–1, 1183, 1433–4. ISBN 978-0-415-97235-2. OCLC 123968757.
  10. ^ John G. M'Kendrick, "Note on a Simple Form of Lippmann's Capillary Electrometer useful to Physiologists".
  11. ^ See also a similar description in German at "Kapillārelektromēter", Meyers Konversationslexikon, Verlag des Bibliographischen Instituts, Leipzig und Wien, 1885–1892. Retrieved 5 December 2010.
  12. ^ . Centre de Recherche Public – Gabriel Lippmann. Archived from the original on 22 July 2011. Retrieved 28 September 2017.
  13. ^ Lippmann, G. (1881). "Principe de la conservation de l'électricité". Annales de chimie et de physique (in French). 24: 145.
  14. ^ Bolas, T. et al: A Handbook of Photography in Colours, Marion & Co. (London, 1900):45–59 (Retrieved from archive.org on 11 February 2010)
  15. ^ Wall, E. J.: Practical Color Photography, American Photographic Publishing Co. (Boston, 1922):185–199 (Retrieved from archive.org on 5 September 2010)
  16. ^ a b Klaus Biedermann, "Lippmann's and Gabor's Revolutionary Approach to Imaging", Nobelprize.org. Retrieved 6 December 2010.
  17. ^ Lippmann, G. (2 March 1908). "Épreuves réversibles. Photographies intégrales". Comptes Rendus de l'Académie des Sciences. 146 (9): 446–451. Bibcode:1908BSBA...13A.245D. Reprinted in Benton "Selected Papers on Three-Dimensional Displays".
  18. ^ Timby, Kim (2015). 3D and Animated Lenticular Photography : Between Utopia and Entertainment. Berlin: De Gruyter. pp. 81–84. ISBN 978-3-11-041306-9.
  19. ^ "La théorie cinétique des gaz et le principe de Carnot". Monatshefte für Mathematik und Physik (in French). 14 (1): A24. 1 December 1903. doi:10.1007/BF01706937. ISSN 1436-5081. S2CID 197661902.
  20. ^ Hoffmann, Peter M (1 March 2016). "How molecular motors extract order from chaos (a key issues review)". Reports on Progress in Physics. 79 (3): 032601. Bibcode:2016RPPh...79c2601H. doi:10.1088/0034-4885/79/3/032601. ISSN 0034-4885. PMID 26863000. S2CID 28867470.
  21. ^ (in French). Académie des sciences. Archived from the original on 2 March 2008. Retrieved 1 March 2008.
  22. ^ Daniel Girardin, "La photographie interférentielle de Lippmann, méthode parfaite et oubliée de reproduction des couleurs", published in DU, die Zeitschrift der Kultur, no 708 : Fotografie, der lange Weg zur Farbe, Juillet-août 2000. Musée de l'Élysée. (in French) Retrieved 6 December 2010.
  23. ^ Bulletin de la Société astronomique de France, 1911, vol. 25, pp. 581–586
  24. ^ "LIPPMANN, Jonas Ferdinand Gabriel". Base Léonore. Government of the French Republic. Retrieved 24 September 2023.
  25. ^ Annuaire du Luxembourg 2015, publ. Editus, p264
  26. ^ "Gabriel Lippmann, Scientist, Dies at Sea", The New York Times, 14 July 1921.

Further reading edit

  • Gabriel Lippmann's colour photography : science, media, museums. Hanin Hannouch. Amsterdam. 2022. ISBN 978-94-6372-855-3. OCLC 1304814408.{{cite book}}: CS1 maint: location missing publisher (link) CS1 maint: others (link)
  • J.P. Pier & J.A. Massard (eds) (1997): Luxembourg, Section des sciences naturelles, physiques et mathématiques de l’Institut grand-ducal de Luxembourg en collaboration avec le Séminaire de mathématique et le Séminaire d’histoire des sciences et de la médecine du centre universitaire de Luxembourg, 139 p.
  • Lebon, Ernest, "Savants du jour : biographie, bibliographie analytique des écrits", comprenant Portrait de Gabriel Lippmann. – 1911. p. 70, Gauthier-Villars (Paris), 1909–1913.
  • Isabelle Bergoend, Le Dagobert optique, Editions Thierry Marchaisse, 2015.

External links edit

 
Wikisource has original works by or about:
Gabriel Lippmann
 
Wikimedia Commons has media related to:
Gabriel Lippmann (category)
  • Gabriel Lippmann on Nobelprize.org   including the Nobel Lecture, 14 December 1908 Colour Photography
  • Gabriel Lippmann in Jewish Encyclopedia

January 01, 1970
gabriel, lippmann, jonas, ferdinand, august, 1845, july, 1921, franco, luxembourgish, physicist, inventor, nobel, laureate, physics, method, reproducing, colours, photographically, based, phenomenon, interference, parents, were, french, jews, lippmann, 1908bor. Jonas Ferdinand Gabriel Lippmann 16 August 1845 13 July 1921 was a Franco Luxembourgish physicist and inventor and Nobel laureate in physics for his method of reproducing colours photographically based on the phenomenon of interference 2 His parents were French Jews Gabriel LippmannLippmann in 1908BornJonas Ferdinand Gabriel Lippmann 1845 08 16 16 August 1845Bonnevoie Bouneweg Luxembourg since 1921 part of Luxembourg City Died13 July 1921 1921 07 13 aged 75 SS France Atlantic OceanNationalityFrenchAlma materEcole Normale SuperieureKnown forLippmann photographyLippmann electrometerElectrowettingIntegral photographyConverse piezoelectric effectAwardsNobel Prize for Physics 1908 Scientific careerFieldsPhysicsInstitutionsSorbonneDoctoral advisorGustav KirchhoffOther academic advisorsHermann von Helmholtz 1 Doctoral studentsMarie Curie Contents 1 Early life and education 2 Career 2 1 The capillary electrometer 2 2 Piezoelectricity 2 3 Colour photography 2 4 Integral photography 2 5 Measurement of time 2 6 The coelostat 2 7 Brownian ratchet 3 Academic affiliations 4 Honours 5 Personal life 6 See also 7 References 8 Further reading 9 External linksEarly life and education editGabriel Lippmann was born in Bonnevoie Luxembourg Luxembourgish Bouneweg on 16 August 1845 3 At the time Bonnevoie was part of the commune of Hollerich Luxembourgish Hollerech which is often given as his place of birth Both places Bonnevoie and Hollerich are now districts of Luxembourg City His father Isaie a French Jew born in Ennery near Metz managed the family glove making business at the former convent in Bonnevoie In 1848 the family moved to Paris where Lippmann was initially tutored by his mother Miriam Rose Levy before attending the Lycee Napoleon now Lycee Henri IV 4 He was said to have been a rather inattentive but thoughtful pupil with a special interest in mathematics In 1868 he was admitted to the Ecole normale superieure in Paris where he failed the agregation examination which would have enabled him to enter the teaching profession preferring instead to study physics In 1872 the French government sent him on a mission to Heidelberg University where he was able to specialize in electricity with the encouragement of Gustav Kirchhoff receiving a doctorate with summa cum laude distinction in 1874 5 Lippmann then returned to Paris in 1875 where he continued to study until 1878 when he became professor of physics at the Sorbonne 6 7 8 At the Sorbonne he was teaching acoustics and optics 9 nbsp Professor Lippmann in the Sorbonne laboratory for research in physics Bibliotheque de la Sorbonne NuBIS Career editLippmann made several important contributions to various branches of physics over the years nbsp Lippmann s electrometer 1872 The capillary electrometer edit One of Lippmann s early discoveries was the relationship between electrical and capillary phenomena which allowed him to develop a sensitive capillary electrometer subsequently known as the Lippmann electrometer which was used in the first ECG machine In a paper delivered to the Philosophical Society of Glasgow on 17 January 1883 John G M Kendrick described the apparatus as follows Lippmann s electrometer consists of a tube of ordinary glass 1 metre long and 7 millimetres in diameter open at both ends and kept in the vertical position by a stout support The lower end is drawn into a capillary point until the diameter of the capillary is 005 of a millimetre The tube is filled with mercury and the capillary point is immersed in dilute sulphuric acid 1 to 6 of water in volume and in the bottom of the vessel containing the acid there is a little more mercury A platinum wire is put into connection with the mercury in each tube and finally arrangements are made by which the capillary point can be seen with a microscope magnifying 250 diameters Such an instrument is very sensitive and Lippmann states that it is possible to determine a difference of potential so small as that of one 10 080th of a Daniell It is thus a very delicate means of observing and as it can be graduated by a compensation method of measuring minute electromotive forces 10 11 Lippmann s PhD thesis presented to the Sorbonne on 24 July 1875 was on electrocapillarity 12 Piezoelectricity edit In 1881 Lippmann predicted the converse piezoelectric effect 13 Colour photography edit nbsp A colour photograph made by Lippmann in the 1890s It contains no pigments or dyes of any kind Above all Lippmann is remembered as the inventor of a method for reproducing colours by photography based on the interference phenomenon which earned him the Nobel Prize in Physics for 1908 7 In 1886 Lippmann s interest turned to a method of fixing the colours of the solar spectrum on a photographic plate On 2 February 1891 he announced to the Academy of Sciences I have succeeded in obtaining the image of the spectrum with its colours on a photographic plate whereby the image remains fixed and can remain in daylight without deterioration 3 By April 1892 he was able to report that he had succeeded in producing colour images of a stained glass window a group of flags a bowl of oranges topped by a red poppy and a multicoloured parrot He presented his theory of colour photography using the interference method in two papers to the Academy one in 1894 the other in 1906 5 nbsp A standing wave The red dots are the wave nodes The interference phenomenon in optics occurs as a result of the wave propagation of light When light of a given wavelength is reflected back upon itself by a mirror standing waves are generated much as the ripples resulting from a stone dropped into still water create standing waves when reflected back by a surface such as the wall of a pool In the case of ordinary incoherent light the standing waves are distinct only within a microscopically thin volume of space next to the reflecting surface Lippmann made use of this phenomenon by projecting an image onto a special photographic plate capable of recording detail smaller than the wavelengths of visible light The light passed through the supporting glass sheet into a very thin and nearly transparent photographic emulsion containing sub microscopically small silver halide grains A temporary mirror of liquid mercury in intimate contact with the emulsion reflected the light back through it creating standing waves whose nodes had little effect while their antinodes created a latent image After development the result was a structure of lamellae a very fine fringe pattern in distinct parallel layers composed of submicroscopic metallic silver grains which was a permanent record of the standing waves Throughout the emulsion the spacing of the lamellae corresponded to the half wavelengths of the light photographed l 2n l being the wavelength of light in air and n is the refractive index of the emulsion Thus colour information was stored locally The larger the separation between the fringes the longer was the wavelength recorded from the image colour red being the longest 9 The finished plate was illuminated from the front at a nearly perpendicular angle using daylight or another source of white light containing the full range of wavelengths in the visible spectrum At each point on the plate light of approximately the same wavelength as the light which had generated the lamellae was strongly reflected back toward the viewer Light of other wavelengths which was not absorbed or scattered by the silver grains simply passed through the emulsion usually to be absorbed by a black anti reflection coating applied to the back of the plate after it had been developed The wavelengths and therefore the colours of the light which had formed the original image were thus reconstituted and a full colour image was seen 14 15 16 In practice the Lippmann process was not easy to use Extremely fine grained high resolution photographic emulsions are inherently much less light sensitive than ordinary emulsions so long exposure times were required With a lens of large aperture and a very brightly sunlit subject a camera exposure of less than one minute was sometimes possible but exposures measured in minutes were typical Pure spectral colours reproduced brilliantly but the ill defined broad bands of wavelengths reflected by real world objects could be problematic The process did not produce colour prints on paper and it proved impossible to make a good duplicate of a Lippmann colour photograph by rephotographing it so each image was unique A very shallow angled prism was usually cemented to the front of the finished plate to deflect unwanted surface reflections and this made plates of any substantial size impractical The size of his early photographs was 4 cm by 4 cm increased later to 6 5 cm by 9 cm 9 The lighting and viewing arrangement required to see the colours to best effect precluded casual use Although the special plates and a plate holder with a built in mercury reservoir were commercially available for a few years c 1900 even expert users found consistent good results elusive and the process never graduated from being a scientifically elegant laboratory curiosity It did however stimulate interest in the further development of colour photography 16 Lippmann s process foreshadowed laser holography which is also based on recording standing waves in a photographic medium Denisyuk reflection holograms often referred to as Lippmann Bragg holograms have similar lamellar structures that preferentially reflect certain wavelengths In the case of actual multiple wavelength colour holograms of this type the colour information is recorded and reproduced just as in the Lippmann process except that the highly coherent laser light passing through the recording medium and reflected back from the subject generates the required distinct standing waves throughout a relatively large volume of space eliminating the need for reflection to occur immediately adjacent to the recording medium Unlike Lippmann colour photography however the lasers the subject and the recording medium must all be kept stable to within one quarter of a wavelength during the exposure in order for the standing waves to be recorded adequately or at all Integral photography edit In 1908 Lippmann introduced what he called integral photography in which a plane array of closely spaced small spherical lenses is used to photograph a scene recording images of the scene as it appears from many slightly different horizontal and vertical locations When the resulting images are rectified and viewed through a similar array of lenses a single integrated image composed of small portions of all the images is seen by each eye The position of the eye determines which parts of the small images it sees The effect is that the visual geometry of the original scene is reconstructed so that the limits of the array seem to be the edges of a window through which the scene appears life size and in three dimensions realistically exhibiting parallax and perspective shift with any change in the position of the observer 17 This principle of using numerous lenses or imaging apertures to record what was later termed a light field underlies the evolving technology of light field cameras and microscopes When Lippmann presented the theoretical foundations of his integral photography in March 1908 it was impossible to accompany them with concrete results At the time the materials necessary for producing a lenticular screen with the proper optical qualities were lacking In the 1920s promising trials were made by Eugene Estanave using glass Stanhope lenses and by Louis Lumiere using celluloid 18 Lippmann s integral photography was the foundation of research on 3D and animated lenticular imagery and also on color lenticular processes Measurement of time edit In 1895 Lippmann evolved a method of eliminating the personal equation in measurements of time using photographic registration and he studied the eradication of irregularities of pendulum clocks devising a method of comparing the times of oscillation of two pendulums of nearly equal period 4 The coelostat edit Lippmann also invented the coelostat an astronomical tool that compensated for the Earth s rotation and allowed a region of the sky to be photographed without apparent movement 4 Brownian ratchet edit In 1900 he proposed what is later called the Brownian ratchet as a purely mechanical version of Maxwell s demon purportedly showing that the kinetic theory of gas is incompatible with the second law of thermodynamics 19 20 Academic affiliations editLippmann was a member of the Academy of Sciences from 8 February 1886 until his death serving as its president in 1912 21 In addition he was a Foreign Member of the Royal Society of London a member of the Bureau des Longitudes 4 and a member of the Grand Ducal Institute of Luxembourg He became a member of the Societe francaise de photographie in 1892 and its president from 1896 to 1899 22 Lippmann was one of the founders of the Institut d optique theorique et appliquee in France Lippmann was the President of the Societe Astronomique de France SAF the French astronomical society from 1903 1904 23 Honours editLippmann was appointed a Knight of the Legion of Honour on 29 December 1881 promoted to Officer on 2 April 1894 to Commander on 14 December 1900 and to the dignity of Grand Officer on 6 December 1919 24 In Luxembourg City an Institute for fundamental scientific research was named after Lippmann Centre de Recherche Public Gabriel Lippmann which merged on 1 January 2015 with another major research centre to form the new Luxembourg Institute for Science and Technology LIST 25 Personal life editLippmann married the daughter of the novelist Victor Cherbuliez in 1888 4 He died on 13 July 1921 aboard the steamer France while en route from Canada 26 See also editAutostereoscopy Brownian ratchet Light field camera List of Jewish Nobel laureatesReferences edit Gabriel Lippmann Mathematics Genealogy Project Retrieved 31 August 2015 Gabriel Lippmann French physicist 12 August 2023 a b Gabriel Lippmann s colour photography science media museums Hanin Hannouch Amsterdam 2022 ISBN 978 94 6372 855 3 OCLC 1304814408 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link CS1 maint others link a b c d e Gabriel Lippmann Nobel Foundation Archived from the original on 5 April 2016 Retrieved 4 December 2010 a b Jacques Bintz Gabriel Lippmann 1845 1921 in Gabriel Lippmann Commemoration par la section des sciences naturelles physiques et mathematiques de l Institut grand ducal de Luxembourg du 150e anniversaire du savant ne au Luxembourg laureat du prix Nobel en 1908 Luxembourg Section des sciences naturelles physiques et mathematiques de l Institut grand ducal de Luxembourg en collaboration avec le Seminaire de mathematique et le Seminaire d histoire des sciences et de la medecine du centre universitaire de Luxembourg 1997 Jean Paul Pier amp Jos A Massard editeurs Luxembourg 1997 Retrieved 4 December 2010 Josef Maria Eder History of Photography 4th ed New York Dover 1978 ISBN 0 486 23586 6 p 668 This Dover edition reproduces the Columbia University Press edition of 1945 the book was originally published in 1932 as Geschichte der Photographie a b From Nobel Lectures Physics 1901 1921 Elsevier Publishing Company Amsterdam 1967 See also the extensive biography on The Nobel Prize in Physics 1908 page a b c Bjelkhagen Hans I 2008 Lippmann Gabriel Jonas 1845 1921 French scientist and physicist In Hannavy John ed Encyclopedia of nineteenth century photography 1st ed New York NY Routledge pp 132 320 647 808 862 3 990 1 1183 1433 4 ISBN 978 0 415 97235 2 OCLC 123968757 John G M Kendrick Note on a Simple Form of Lippmann s Capillary Electrometer useful to Physiologists See also a similar description in German at Kapillarelektrometer Meyers Konversationslexikon Verlag des Bibliographischen Instituts Leipzig und Wien 1885 1892 Retrieved 5 December 2010 About Gabriel Lippmann Centre de Recherche Public Gabriel Lippmann Archived from the original on 22 July 2011 Retrieved 28 September 2017 Lippmann G 1881 Principe de la conservation de l electricite Annales de chimie et de physique in French 24 145 Bolas T et al A Handbook of Photography in Colours Marion amp Co London 1900 45 59 Retrieved from archive org on 11 February 2010 Wall E J Practical Color Photography American Photographic Publishing Co Boston 1922 185 199 Retrieved from archive org on 5 September 2010 a b Klaus Biedermann Lippmann s and Gabor s Revolutionary Approach to Imaging Nobelprize org Retrieved 6 December 2010 Lippmann G 2 March 1908 Epreuves reversibles Photographies integrales Comptes Rendus de l Academie des Sciences 146 9 446 451 Bibcode 1908BSBA 13A 245D Reprinted in Benton Selected Papers on Three Dimensional Displays Timby Kim 2015 3D and Animated Lenticular Photography Between Utopia and Entertainment Berlin De Gruyter pp 81 84 ISBN 978 3 11 041306 9 La theorie cinetique des gaz et le principe de Carnot Monatshefte fur Mathematik und Physik in French 14 1 A24 1 December 1903 doi 10 1007 BF01706937 ISSN 1436 5081 S2CID 197661902 Hoffmann Peter M 1 March 2016 How molecular motors extract order from chaos a key issues review Reports on Progress in Physics 79 3 032601 Bibcode 2016RPPh 79c2601H doi 10 1088 0034 4885 79 3 032601 ISSN 0034 4885 PMID 26863000 S2CID 28867470 Les Membres de l Academie des sciences depuis sa creation en 1666 in French Academie des sciences Archived from the original on 2 March 2008 Retrieved 1 March 2008 Daniel Girardin La photographie interferentielle de Lippmann methode parfaite et oubliee de reproduction des couleurs published in DU die Zeitschrift der Kultur no 708 Fotografie der lange Weg zur Farbe Juillet aout 2000 Musee de l Elysee in French Retrieved 6 December 2010 Bulletin de la Societe astronomique de France 1911 vol 25 pp 581 586 LIPPMANN Jonas Ferdinand Gabriel Base Leonore Government of the French Republic Retrieved 24 September 2023 Annuaire du Luxembourg 2015 publ Editus p264 Gabriel Lippmann Scientist Dies at Sea The New York Times 14 July 1921 Further reading editGabriel Lippmann s colour photography science media museums Hanin Hannouch Amsterdam 2022 ISBN 978 94 6372 855 3 OCLC 1304814408 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link CS1 maint others link J P Pier amp J A Massard eds 1997 Gabriel Lippmann Commemoration par la section des sciences naturelles physiques et mathematiques de l Institut grand ducal de Luxembourg du 150e anniversaire du savant ne au Luxembourg laureat du prix Nobel en 1908 Luxembourg Section des sciences naturelles physiques et mathematiques de l Institut grand ducal de Luxembourg en collaboration avec le Seminaire de mathematique et le Seminaire d histoire des sciences et de la medecine du centre universitaire de Luxembourg 139 p Lebon Ernest Savants du jour biographie bibliographie analytique des ecrits comprenant Portrait de Gabriel Lippmann 1911 p 70 Gauthier Villars Paris 1909 1913 Isabelle Bergoend Le Dagobert optique Editions Thierry Marchaisse 2015 External links edit nbsp Wikisource has original works by or about Gabriel Lippmann nbsp Wikimedia Commons has media related to Gabriel Lippmann category Gabriel Lippmann on Nobelprize org nbsp including the Nobel Lecture 14 December 1908 Colour Photography Gabriel Lippmann in Jewish Encyclopedia Centre de Recherche Public Gabriel Lippmann Retrieved from https en wikipedia org w index php title Gabriel Lippmann amp oldid 1215413444, wikipedia, wiki, book, books, library,

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