1955 1955. George Maxwell: à moi de jouer. /Sogedide 1955 . George Maxwell: à moi de jouer. /Sogedide 1955
Etat correct
Garber (Elizabeth), Brush (Stephen G.) and Everitt (C.W.F.) - James Clerk Maxwell
Reference : 100203
(1986)
The MIT Press Malicorne sur Sarthe, 72, Pays de la Loire, France 1986 Book condition, Etat : Bon hardcover, editor's full black clothes binding, no dust-jacket grand In-8 1 vol. - 592 pages
few text-figures 1st edition, 1986 Contents, Chapitres : Contents, List of serial abbreviations, preface, xxvii, Text, 565 pages - Kinetic theory and the properties of gases : Maxwell's work in its Nineteenth-century context - Documents on atomic and statistical physics - Documents on the kinetic theory of gases (Letters, notes, postcard, various documents) - James Clerk Maxwell (13 juin 1831 à Édimbourg en Écosse - 5 novembre 1879 à Cambridge en Angleterre) est un physicien et mathématicien écossais. Il est principalement connu pour avoir unifié en un seul ensemble d'équations, les équations de Maxwell, l'électricité, le magnétisme et l'induction, en incluant une importante modification du théorème d'Ampère. Ce fut à l'époque le modèle le plus unifié de l'électromagnétisme. Il est également célèbre pour avoir interprété, dans un article en quatre parties publié dans Philosophical Magazine intitulé On Physical Lines of Force, la lumière comme étant un phénomène électromagnétique en s'appuyant sur les travaux de Michael Faraday. Il a notamment démontré que les champs électriques et magnétiques se propagent dans l'espace sous la forme d'une onde et à la vitesse de la lumière. Ces deux découvertes permirent d'importants travaux ultérieurs notamment en relativité restreinte et en mécanique quantique. Il a également développé la distribution de Maxwell, une méthode statistique de description de la théorie cinétique des gaz. Maxwell est considéré par de nombreux physiciens comme le scientifique du xixe siècle ayant eu le plus d'influence au xxe siècle. Ses contributions à la science sont considérées par certains comme aussi importantes que celles d'Isaac Newton ou d'Albert Einstein. En 1931, pour le centenaire de la naissance de Maxwell, Einstein lui-même décrivait les travaux de Maxwell comme les « plus profonds et fructueux que la physique ait connus depuis le temps de Newton ». Il est également connu pour avoir réalisé le 17 mai 1861 la première photographie en vraie couleur devant les membres de la Royal Institution de Londres. - Une des contributions les plus importantes de Maxwell est la théorie cinétique des gaz. Initiée par Daniel Bernoulli, cette théorie a ensuite été développée successivement par John Herapath, John James Waterston, James Joule et surtout Rudolf Clausius, jusqu'à être largement acceptée. Néanmoins elle reçut un développement important de la part de Maxwell. En 1866, il formule, indépendamment de Ludwig Boltzmann, la théorie cinétique des gaz dite de Maxwell-Boltzmann. Sa formule, appelée distribution de Maxwell, donne la proportion des molécules d'un gaz se développant à une certaine vitesse à une température donnée. Cette approche généralise les lois de la thermodynamique et permet d'expliquer statistiquement un certain nombre d'observations expérimentales. Les travaux de Maxwell en thermodynamique l'amènent également à formuler l'expérience de pensée appelée le démon de Maxwell. En 1871 il établit les relations thermodynamiques de Maxwell, qui expriment l'égalité entre certaines dérivées secondes des potentiels thermodynamiques par rapport à différentes variables thermodynamiques. En 1874, il construit un moulage en plâtre afin de visualiser les transitions de phase, modèle basé sur les méthodes graphiques de thermodynamique avancées par le chercheur américain Josiah Willard Gibbs. (source : Wikipedia) very good copy, the editor's binding is clean and unmarked, very lightly dusty on the borders, it remains clean, inside is fine no markings, no dust-jacket
Librairie Scientifique A. Hermann à Paris Malicorne sur Sarthe, 72, Pays de la Loire, France 1902 Book condition, Etat : Bon broché, sous couverture imprimée éditeur grise grand In-8 1 vol. - 228 pages
1ere édition de 1902 Contents, Chapitres : Introduction - 1. Les électrostatiques de Maxwell : Les propriétés fondamentales des diélectriques, les doctrines de Faraday et Mossotti - La première électrostatique de Maxwell - La deuxième électrostatique de Maxwell - La troisième électrostatique de Maxwell - 2. L'électrodynamique de Maxwell : Flux de conduction et flux de déplacement - Les six équations de Maxwell et l'énergie électromagnétique - La théorie électromagnétique de la lumière - Conclusion - - James Clerk Maxwell (13 juin 1831 à Édimbourg en Écosse - 5 novembre 1879 à Cambridge en Angleterre) est un physicien et mathématicien écossais. Il est principalement connu pour avoir unifié en un seul ensemble d'équations, les équations de Maxwell, l'électricité, le magnétisme et l'induction, en incluant une importante modification du théorème d'Ampère. Ce fut à l'époque le modèle le plus unifié de l'électromagnétisme. Il est également célèbre pour avoir interprété, dans un article en quatre parties publié dans Philosophical Magazine intitulé On Physical Lines of Force, la lumière comme étant un phénomène électromagnétique en s'appuyant sur les travaux de Michael Faraday. Il a notamment démontré que les champs électriques et magnétiques se propagent dans l'espace sous la forme d'une onde et à la vitesse de la lumière. Ces deux découvertes permirent d'importants travaux ultérieurs notamment en relativité restreinte et en mécanique quantique. Il a également développé la distribution de Maxwell, une méthode statistique de description de la théorie cinétique des gaz. Maxwell est considéré par de nombreux physiciens comme le scientifique du xixe siècle ayant eu le plus d'influence au xxe siècle. Ses contributions à la science sont considérées par certains comme aussi importantes que celles d'Isaac Newton ou d'Albert Einstein. En 1931, pour le centenaire de la naissance de Maxwell, Einstein lui-même décrivait les travaux de Maxwell comme les « plus profonds et fructueux que la physique ait connus depuis le temps de Newton ». Il est également connu pour avoir réalisé le 17 mai 1861 la première photographie en vraie couleur devant les membres de la Royal Institution de Londres. - Pierre Maurice Marie Duhem, né le 10 juin 1861 à Paris 2e et mort le 14 septembre 1916 à Cabrespine, est un physicien, chimiste, historien et épistémologue français. (source : Wikipedia) couverture en bon état mais avec un petit trou de 1 cm de diametre environ sur le haut du plat inférieur, infime déchirure sans manque sur le bord gauche du plat supérieur, affectant à peine le bord du dos sur 1 cm, la couverture reste en bon état, intérieur sinon frais et propre, papier à peine jauni
"MAXWELL, JAMES CLERK. - THE ""MAXWELL-DISTRIBUTION""S FINAL FORM.
Reference : 41873
(1866)
(London, Taylor and Francis, 1866). No wrappers, as extracted from""Proceedings of the Royal Society of London."", Vol. XV. May 16, 1866. Pp 167-171.
First appearance of this seminal paper (in the abstract-version from ""Proceedings""), representing the announcement of Maxwell's final ""Theory of Gases"" and introduces the ""Maxwell Distribution"" in its final form, a statistical means of describing aspects of the kinetic theory of gases, a theory, together with his electromagnetic theory, are considered to be some of the greatest advances in physics of all times. The paper offered, only 5 pages, is an abstract of a paper with the same title, which was printed in full in ""Philosophical Transactions"" in 1868. Everett considers this paper (1868) to be Maxwell's greatest single paper.The ""abstract"", which announces his discovery was printed the year before the larger paper. Maxwell's discoveries laid the foundations of special relativity and quantum mechanics.One of Maxwell's major investigations was on the kinetic theory of gases. Originating with Daniel Bernoulli, this theory was advanced by the successive labours of John Herapath, John James Waterston, James Joule, and particularly Rudolf Clausius, to such an extent as to put its general accuracy beyond a doubt" but it received enormous development from Maxwell, who in this field appeared as an experimenter (on the laws of gaseous friction) as well as a mathematician.In 1866, he formulated statistically, independently of Ludwig Boltzmann, the Maxwell-Boltzmann kinetic theory of gases. His formula, called the Maxwell distribution, gives the fraction of gas molecules moving at a specified velocity at any given temperature. In the kinetic theory, temperatures and heat involve only molecular movement. This approach generalized the previously established laws of thermodynamics and explained existing observations and experiments in a better way than had been achieved previously. Maxwell's work on thermodynamics led him to devise the Gedankenexperiment (thought experiment) that came to be known as Maxwell's demon.
"MAXWELL, JAMES CLARK. - THE ""MAXWELL-DISTRIBUTION""S FINAL FORM - A MAIN PAPER IN 19TH CENTURY PHYSICS.
Reference : 43456
(1867)
London, Taylor and Francis, 1867. 4to. No wrappers as extracted from ""Philosophical Transactions"", Vol. 157 - Part I. Titlepage to volume 155 and pp. 49-88. Titlepage with minor light browning at corners. Internally clean. A small stamp on verso of titlepage.
First appearance of this seminal paper (in its full version from ""Transactions""), representing the announcement of Maxwell's final ""Theory of Gases"" and introduces the ""Maxwell Distribution"" in its final form, a statistical means of describing aspects of the kinetic theory of gases, a theory, together with his electromagnetic theory, are considered to be SOME OF THE GREATEST ADVANCES IN PHYSICS OF ALL TIMES. Everett considers this paper (1868) to be Maxwell's greatest single paper. Maxwell's discoveries laid the foundations of special relativity and quantum mechanics.One of Maxwell's major investigations was on the kinetic theory of gases. Originating with Daniel Bernoulli, this theory was advanced by the successive labours of John Herapath, John James Waterston, James Joule, and particularly Rudolf Clausius, to such an extent as to put its general accuracy beyond a doubt" but it received enormous development from Maxwell, who in this field appeared as an experimenter (on the laws of gaseous friction) as well as a mathematician.In 1866, he formulated statistically, independently of Ludwig Boltzmann, the Maxwell-Boltzmann kinetic theory of gases. His formula, called the Maxwell distribution, gives the fraction of gas molecules moving at a specified velocity at any given temperature. In the kinetic theory, temperatures and heat involve only molecular movement. This approach generalized the previously established laws of thermodynamics and explained existing observations and experiments in a better way than had been achieved previously. Maxwell's work on thermodynamics led him to devise the Gedankenexperiment (thought experiment) that came to be known as Maxwell's demon.
London, Taylor and Francis, 1867. 4to. Extracted and rebound in recent green plain wrappers. Title-page of vol. 157 pasted on to front wrapper. A fine copy. Pp. 49-88.
First appearance of this seminal paper (in its full version from ""Transactions""), representing the announcement of Maxwell's final ""Theory of Gases"" and introduces the ""Maxwell Distribution"" in its final form, a statistical means of describing aspects of the kinetic theory of gases, a theory, together with his electromagnetic theory, are considered to be SOME OF THE GREATEST ADVANCES IN PHYSICS OF ALL TIMES. Everett considers this paper (1868) to be Maxwell's greatest single paper. Maxwell's discoveries laid the foundations of special relativity and quantum mechanics.One of Maxwell's major investigations was on the kinetic theory of gases. Originating with Daniel Bernoulli, this theory was advanced by the successive labours of John Herapath, John James Waterston, James Joule, and particularly Rudolf Clausius, to such an extent as to put its general accuracy beyond a doubt" but it received enormous development from Maxwell, who in this field appeared as an experimenter (on the laws of gaseous friction) as well as a mathematician.In 1866, he formulated statistically, independently of Ludwig Boltzmann, the Maxwell-Boltzmann kinetic theory of gases. His formula, called the Maxwell distribution, gives the fraction of gas molecules moving at a specified velocity at any given temperature. In the kinetic theory, temperatures and heat involve only molecular movement. This approach generalized the previously established laws of thermodynamics and explained existing observations and experiments in a better way than had been achieved previously. Maxwell's work on thermodynamics led him to devise the Gedankenexperiment (thought experiment) that came to be known as Maxwell's demon.
London, Taylor and Francis, 1864. 4to. In plain white paper-wrappers with title-page of journal volume pasted on to front wrapper. In ""Transactions of the Cambridge Philosophical Society"", Volume 10. Fine and clean. Pp. (27)-83, (1) + the pasted on title-page.
First appearance of Maxwell's landmark - and his very first published on electromagnetism - paper in which he anticipates many of the fundamental ideas presented in his famous four-part paper ""On Physical Lines of Force"" (1861-2) in which he derived the equations of electromagnetism. The present paper ushered in a new era of classical electrodynamics and catalyzed further progress in the mathematical field of vector calculus. Because of this, it is considered one of the most historically significant publications in the field of physics and of science in general.Maxwell began his researches on electromagnetism following the completion of his studies at Cambridge in 1854. They were aimed at constructing, at a theoretical level, a unified mathematical theory of electric and magnetic phenomena that would express the methods and ideas of Faraday as an alternative to the theory of Weber."" This programme was announced in his first article, 'On Faraday's lines of force', in 1856, and continued in two other major texts, 'On physical lines of force' in 1861-1862 and 'A dynamical theory of the electromagnetic field' in 1865. According to a famous passage in its preface, the Treatise (1873) represented the outcome of this programme"" (Landmark Writings, p. 569). ""Maxwell's first paper, ""On Faraday's Line of Force"" (1855-1856), was divided into two parts, with supplementary) examples. Its origin may he traced in a long correspondence with Thomson, edited by Larmor in 1936. Part 1 was an exposition of the analogy between lines of force and streamlines in an incompressible fluid. It contained one notable extension to Thomson's treatment of the subject and also an illuminating opening discourse on the philosophical significance of analogies between different branches of physics. This was a theme to which Maxwell returned more than once. His biographers print in full an essay entitled ""Analogies in Nature,"" which he read a few months later (February 1856) to the famous Apostles Club at Cambridge" this puts the subject in a wider setting and deserves careful reading despite its involved and cryptic style. Here, as elsewhere, Maxwell's metaphysical speculation discloses the influence of Sir William Hamilton, specifically of Hamilton's Kantian view that all human knowledge is of relations rather than of things. The use Maxwell saw in the method of analogy was twofold. It crossfertilized technique between different fields, and it served as a golden mean between analytic abstraction and the method of hypothesis. The essence of analogy (in contrast with identity) being partial resemblance, its limits must be recognized as clearly as its existence" yet analogies may help in guarding against too facile commitment to a hypothesis. The analogy of an electric current to two phenomena as different as conduction of heat and the motion of a fluid should, Maxwell later observed, prevent physicists from hastily assuming that ""electricity is either a substance like water, or a state of agitation like heat. ""The analogy is geometrical: ""a similarity between relations, not a similarity between the things related."""" (DSB)The 1856 paper has been eclipsed by Maxwell's later work, but its originality and importance are greater than is usually thought. Besides interpreting Faraday's work and giving the electrotonic function, it contained the germ of a number of ideas which Maxwell was to revive or modify in 1868 and later an integral representation of the field equations (1868),the treatment of electrical action as analogous to the motion of an incompressible fluid (1869, 1873), the classification of vector functions into forces and fluxes (1870), and an interesting formal symmetry in the equations connecting A, B, E, and H, different from the symmetry commonly recognized in the completed field equations. The paper ended with solutions to a series of problems, including an application of the electrotonic function to calculate the action of a magnetic field on a spinning conducting sphere.
Edimbourg, Londres, 1855, 1860, in-4, 4 pièces en 1 volume, demi-chagrin noir moderne, Ce recueil ouvre sur les mémoires fondamentaux de James Clerck MAXWELL (1831-1879) sur la perception des couleurs, en éditions originales : - "Experiments on colour, as perceived by the eye, with remarks on colour-blindness". Extrait des Transactions of The Royal Society of Edinburgh, vol. XXI, part. II, 1855. Paginé 275 à 298. 1 planche en lithographie. - "On the theory of compound colours, and the relations of the colours of the spectrum". Extrait des Philosophical Transactions of the Royal Society of London, vol. 150, 1860. Paginé 57 à 84. 2 planches en lithographie. Le premier mémoire, lu le 19 mars 1855, est illustré d'une planche qui représente la toupie et les disques utilisés par Maxwell pour ses expériences au sein du laboratoire de J. D. Forbes à Édimbourg, un diagramme de couleurs selon le principe de Newton et un autre selon les expériences du Dr D.R. Hay, auteur d'un ouvrage de 1839 intitulé Nomenclature of Colours. Il inaugure une série de travaux publiés par le célèbre physicien sur la vision des couleurs et sur le daltonisme, à partir des expériences qu'il mena dès 1849 à Édimbourg et qui le conduisirent à confirmer l'hypothèse de Young : toutes les couleurs peuvent naître du mélange de trois couleurs du spectre, pourvu que l'on puisse additionner aussi bien que soustraire les stimuli lumineux. Le second article, lu devant la Royal Society le 22 Mars 1860, contient sa théorie définitive. Dans ce mémoire, illustré de deux planches de diagrammes, Maxwell décrit ses expériences et les instruments qu'il a mis au point pour les mener. La théorie des valeurs trichromatiques de Maxwell est considérée comme l'origine de la colorimétrie. Elle marque le retour de la physique et de la mesure de la lumière et de la couleur dans l'histoire scientifique. Sa méthode est à l'origine de la première photographie en couleurs, le cliché d'un ruban de tartan pris par Thomas Sutton, qu'il projette en 1861 devant un public où figure entre autres de Faraday. Les découvertes de Maxwell ont été récompensées par la médaille Rumford en 1860. Deux autres pièces ont été jointes à la suite : - George WILSON : "On the extent to which the received Theory of vision requires us to regard the eye as a camera obscura". Extrait des Transactions of The Royal Society of Edinburgh, vol. XXI, part. II, 1855. Paginé 327-347. Article qui a été publié à la suite des "Experiments on colour" de Maxwell. George Wilson, directeur du Musée Industriel d'Écosse, fut le premier à proposer une analyse statistique du daltonisme. Ses travaux ont servi à Maxwell pour ses recherches. - John William STRUTT, lord RAYLEIGH (1842-1919) : "On the colours of thin plates". Transactions of The Royal Society of Edinburgh, vol. XXXIII, 1885. Paginé 157-170. 1 planche dépliante en lithographie représentant un diagramme des couleurs. In fine a été rajoutée une planche dessinée à l'encre et légendée en français d'un diagramme de la série de couleurs. On joint, placée à la fin, une lettre manuscrite rédigée par un assistant bibliothécaire, John Hardy, au nom du Dr. Tscherning, secrétaire de la Royal Society of Edinburgh : elle s'adresse à son correspondant français, pour le dispenser de payer ces "soiled and broken copies" qui lui ont été envoyées. Quelques petits papillons manuscrits ont été contrecollés dans le second mémoire de Maxwell. DSB IX, pp. 200 et suiv. "James Clerck Maxwell" sur Colorsystem [en ligne]. Couverture rigide
Bon 4 pièces en 1 volume
Cavendish Laboratory - T.C. Fitzpatrick - Arthur Schuster on Clerk Maxwell - R.T. Glazebrook on Rayleigh - Sir Joseph John Thomson - H.F. Newall - Ernest Rutherford - C.T.R. Wilson - N.R. Campbell - L. R. Wilberforce
Reference : 100740
(1910)
Longmans, Green and Co, London Malicorne sur Sarthe, 72, Pays de la Loire, France 1910 Book condition, Etat : Bon hardcover, editor's binding, full green clothes, no dust-jacket grand In-8 1 vol. - 353 pages
1 plate in frontispiece, 3 collotype plates (portraits of James Clerk Maxwell, Lord Rayleigh and Joseph John Thomson) and 7 other plates of the laboratory (complete of the 11 plates) 1st edition, 1910 Contents, Chapitres : Preface, Contents, List of Illustrations, xi, Text, 342 pages, catalogue Longmans, ii - T.C. Fitzpatrick : The building of the laboratory - Arthur Schuster : The Clerk Maxwell period - R.T. Glazebrook : The Rayleigh period - Sir Joseph John Thomson : Survey of the last 20 years - H.F. Newall : 1885-1894 - Ernest Rutherford : 1895-1898 - Charles Thomson Rees Wilson : 1899-1902 - N.R. Campbell : 1903-1909 - L. R. Wilberforce : The development of the teaching of physics - List of memoirs containing accounts of research performed in the Cavendish Laboratory - List of thoses who have worked in the Laboratory - Index - Le laboratoire Cavendish (Cavendish Laboratory) est le département de physique de l'université de Cambridge. Il fait partie de l'école de sciences physiques. Il a ouvert en 1874 comme l'un des premiers laboratoires d'enseignement en Angleterre. Son nom honore Henry Cavendish, fameux physicien anglais de la fin du xviiie siècle. - The Cavendish Laboratory is the Department of Physics at the University of Cambridge, and is part of the School of Physical Sciences. The laboratory was opened in 1874 on the New Museums Site as a laboratory for experimental physics and is named after the British chemist and physicist Henry Cavendish. The laboratory has had a huge influence on research in the disciplines of physics and biology. As of 2019, 30 Cavendish researchers have won Nobel Prizes. Notable discoveries to have occurred at the Cavendish Laboratory include the discovery of the electron, neutron, and structure of DNA. - Professor James Clerk Maxwell, the developer of electromagnetic theory, was a founder of the laboratory and the first Cavendish Professor of Physics. The Duke of Devonshire had given to Maxwell, as head of the laboratory, the manuscripts of Henry Cavendish's unpublished Electrical Works. The editing and publishing of these was Maxwell's main scientific work while he was at the laboratory. Cavendish's work aroused Maxwell's intense admiration and he decided to call the Laboratory (formerly known as the Devonshire Laboratory) the Cavendish Laboratory and thus to commemorate both the Duke and Henry Cavendish. Several important early physics discoveries were made here, including the discovery of the electron by J.J. Thomson (1897) the Townsend discharge by John Sealy Townsend, and the development of the cloud chamber by C.T.R. Wilson. Ernest Rutherford became Director of the Cavendish Laboratory in 1919. near fine copy, the binding is rather fine, without dust-jacket, supposingly as issued, the binding is nice and unmarked, a very small spot on the bottom part, the title on the spine is mainly erased, inside is fine, no markings, paper is fine, name of the former owner on the first page, complete of the 11 plates, with 3 wonderful portraits of Clerk Maxwell, Rayleigh and Thomson, 2 studies were written by J.J. Thomson (discovery of the electron, 1897) and Ernest Rutheford, both were nobelized after .Rutherford was in Manchester when he got the Nobel in 1911 but, under his leadership the neutron was discovered by James Chadwick in 1932
Dover , Dover Books on Physics and Chemistry Malicorne sur Sarthe, 72, Pays de la Loire, France 1991 Book condition, Etat : Bon paperback, editor's black printed wrappers with a red circle In-8 1 vol. - 175 pages
a portrait of J. Clerk Maxwell in frontispiece, few text-figures reprint 1991 of the 1952's edition (1st edition was 1876) "Contents, Chapitres : Preface (1877), Note, Biographical note, Contents, xii, Text, 163 pages and Dover catalogue - Introduction - On motion - On force - On the properties of the centre of mass of a material system - On work and energy - Recapitulation - The pendulum and gravity - Universal gravitation - On the equations of motion of a connected system - Appendix : The relativity of the forces of nature - The principle of least action - James Clerk Maxwell (13 juin 1831 à Édimbourg en Écosse - 5 novembre 1879 à Cambridge en Angleterre) est un physicien et mathématicien écossais. Il est principalement connu pour avoir unifié en un seul ensemble d'équations, les équations de Maxwell, l'électricité, le magnétisme et l'induction, en incluant une importante modification du théorème d'Ampère. Ce fut à l'époque le modèle le plus unifié de l'électromagnétisme. Il est également célèbre pour avoir interprété, dans un article en quatre parties publié dans Philosophical Magazine intitulé On Physical Lines of Force, la lumière comme étant un phénomène électromagnétique en s'appuyant sur les travaux de Michael Faraday. Il a notamment démontré que les champs électriques et magnétiques se propagent dans l'espace sous la forme d'une onde et à la vitesse de la lumière. Ces deux découvertes permirent d'importants travaux ultérieurs notamment en relativité restreinte et en mécanique quantique. Il a également développé la distribution de Maxwell, une méthode statistique de description de la théorie cinétique des gaz. - In 1865 Maxwell resigned the chair at King's College, London, and returned to Glenlair with Katherine. In his paper 'On governors' (1868) he mathematically described the behaviour of governors, devices that control the speed of steam engines, thereby establishing the theoretical basis of control engineering. In his paper ""On reciprocal figures, frames and diagrams of forces"" (1870) he discussed the rigidity of various designs of lattice. He wrote the textbook Theory of Heat (1871) and the treatise Matter and Motion (1876). Maxwell was also the first to make explicit use of dimensional analysis, in 1871. (source : Wikipedia)" minor folding tracks on the corner of the wrappers, minor wear on the front-part of the wrappers, else near fine copy, no markings, inside is fine and complete of the plate in frontispiece, portrait of J.C. Maxwell - Dover Edition
(London, Taylor and Francis, 1860). 8vo. In the original printed wrappers. In ""Proceedings of the Royal Society"", Vol. X [10], No. 39. Entire issue offered. Wrappers with a few brown spots, fine and clean. Pp. 404-408. [Entire issue: Pp. 319-494].
First printing of Maxwell's paper on a method of exhibiting the relations of colours.""Maxwell worked on the generation of white light by mixing different colors and in 1860, published the paper On the Theory of Compound Colours and its Relations to the Colours of the. In this paper, he extended the work of Thomas Young who first postulated only three colors, red, green and violet are necessary to produce any color including white and not all the colors of the spectrum are necessary as first illustrated by Newton. He also incorporated Hermann G?nther Grassman's concept that there are three variables of color vision (spectral color, intensity of illumination and the degree of saturation). Maxwell showed that these color variables can be represented on a color diagram based on three primary colors. While Newton distinguished his principal colors from the painters triad of primary colors (red, yellow and blue), he supposed the identity of mixing rule for lights and pigments. Even though Helmholtz explained that the mixture of color lights is an additive process while the mixture of pigments is a subtractive process as illustrated in Figure 2, Maxwell made experiments and developed a complete theory to explain how this happens by creating a color triangle which was originally suggested by James David Forbes and illustrated that any color can be generated with a mixture of any three primary colors and that a normal eye has three sorts of receptors as illustrated in his 1861 paper On the Theory of Three Primary Colours. He chose the three primary colors as red, green, and blue."" (Sarkar, Pp. 4-5). From 1855 to 1872, Maxwell published at intervals a series of valuable investigations concerning the perception of colour, colour-blindness and colour theory, for the earlier of which the Royal Society awarded him the Rumford Medal. The instruments which he devised for these investigations were simple and convenient to use. For example, Maxwell's discs were used to compare a variable mixture of three primary colours with a sample colour by observing the spinning ""colour top."".
2016 346 pages 2016. Broché. 346 pages.
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2007 240 pages in12. 2007. Broché. 240 pages.
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Mysterious Pr 1986 317 pages 23x16x4cm. 1986. Relié. 317 pages. Traduit de Sénès Florence - Illustrations de Jankovics györgy
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LA MAISON DU SAULE 1997 155 pages poche. 1997. Broché. 155 pages. Traduit de Sénès Florence - Illustrations de Jankovics györgy
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1996 1996. ouvrage broché 174 pages aux éditions du Saule en très BON ETAT complet et solide sans déchirures intérieur propre et encore frais
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1998 1998. 1998 broché couverture souple. Globalement livre en bon état d'usage
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Maxwell J. (Maxwell K.) The Theory of Heat in the Elementary Processing of Clerk Maxwell. In Russian (ask us if in doubt)/Maksvell Dzh. (Maksuell K.) Teoriya teploty v elementarnoy obrabotke Klerk Maksuellya. Short description: In Russian (ask us if in doubt).Kyiv: Typography by I.N. Kushnarev 1888. 292 p. We have thousands of titles and often several copies of each title may be available. Please feel free to contact us for a detailed description of the copies available. SKUalbea69099f3be1d0fa
"MAXWELL, JAMES CLARK. - THE INTRODUCTION OF THE ""ELECTRICAL FORMULATION"" OF THE ELECTROMAGNETIC THEORY OF LIGHT.
Reference : 42029
(1869)
(London, Taylor & Francis, 1869) Large 4to. Without wrappers. Extracted from ""Philosophical Transactions of the Royal Society of London."", Vol. 158. Maxwell's paper: pp. 643-657. Clean and fine, wide margins.
First appearance of this major paper on electromagnetic dynamics, in which Maxwell improves the groundbreaking equations he had set forth in his famous paper of 1865, the ""A dynamical Theory of Electro-Magnetic Fields"". In the paper offered here, he for the first time proposed to base the electromagnetic theory of light solely on 2 equations. The paper is one of Maxwell's 5 most importent contributions to electromagnetism.""Formulas for the forces between moving charged bodies may indeed de derived from Maxwell's equations, but the action is not along the line joining them and can be reconciled with a dynamical principle only by taking into account the exchange of momentum with the field. Maxwell remarked that the equations might be condensed, but ""to eliminate a quantity which expresses a useful idea would be rather a loss than a gain in this stage of our enquiry."" he had in fact simplified the equations in his fifth major paper, the short, but importent ""Note on the Electromagnetic Theory of Light."" (1868), writing them in an integral form without the function A, based on four postulates derived from electrical experiments. This may be called the electrical formulation of the theory, in contrast with the original dynamical formulation."" (C.W.F. Everitt in DSB).
(London, Taylor and Francis, 1866). Large 4to. Without wrappers. Extracted from ""Philosophical Transactions of the Royal Society of London."", Vol. 156 - Part I. Pp. 249-268 a. 1 lithographed plate. A few brownspots to the plate. Having the titlepage to vol. 156 - Part I. A few brownspots to lower margins.
First appearance of a major paper in the kinetic theory of gases, in which Maxwell proved that the viscosity was independent of pressure as predicted, and nearly a linear function of the absolute temperature T.One of Maxwell's major investigations was on the kinetic theory of gases. Originating with Daniel Bernoulli, this theory was advanced by the successive labours of John Herapath, John James Waterston, James Joule, and particularly Rudolf Clausius, to such an extent as to put its general accuracy beyond a doubt"" but it received enormous development from Maxwell, who in this field appeared as an experimenter (on the laws of gaseous friction) as well as a mathematician.""James Clerk Maxwell published a famous paper in 1866 (the paper offered) using the kinetic theory of gases to study gaseous viscosity. The internal friction (the viscosity) of the gas is determined by the probability a particle of layer A enters layer B with a corresponding transfer of momentum. Maxwell's calculations showed him that the viscosity coefficient is proportional to both the density, the mean free path and the mean velocity of the atoms. On the other hand, the mean free path is inversely proportional to the density. So an increase of pressure doesn't result in any change of the viscosity.