mendeleev d (12 Ergebnisse)

Hardcover. Zustand: Fine. Zustand des Schutzumschlags: Fine. 4th Edition. 4th edition ; 239 pp. ; chiefly color illustrations ; 32 cm. ; text in Russian and English ; ISBN: 5852503983; 9785852503985 ; OCLC: 29649767 ; "avtor s"emki Vil'iam Mendeleev ; avtor teksta Aida Nasibova ; khudozhnik Nenad Dogan ; perevod s russkog o Artura Shkarovskogo-Raffe." ; red silk with embossed Cyrillic lettering, in color photographic dustjacket ; features color photographs of the artworks and artifacts, including the Imperial regalia, to be seen in the state apartments and churches o f the Kremlin ; crease to back dustjacket flap and back endpaper, small nicks to top of dustjacket at spine, else FINE/FINE [This online listing contains text in Russian fonts]. Book.

Zustand: New. In.

Zustand: New. In.

Hardcover/Hardback. Zustand: As New. Rabota D.I. Mendeleeva 1905, v kotoroj on govorit o zhelatelnykh putyakh razvitiya Rossii: v geopoliticheskoj, ekonomicheskoj i nauchnoj oblastyakh.

Paris, Gauthier-Villars, 1876. 4to. No wrappers. In: "Comptes Rendus Hebdomadaires des Séances de L'Academie des Sciences", Tome 82, No 7. Pp. (397-) 428. Mendelejeff's paper: pp. 412-415. Clean and fine. First printing of one of the papers which marks the beginning of Mendeléeff's aeronautical recherches to which he turned after his discovery of the periodic table. These researches were stimulated by his interest in the gas-laws of Boyle-Mariotte and Gay-Lussac and aimed at establishing the ontology of the ether.

Paris, Gauthier-Villars, 1876. 4to. No wrappers. In: "Comptes Rendus Hebdomadaires des Séances de L'Academie des Sciences", Tome 82, No 8. Pp. (429-) 467. Mendelejeff & Kaiander's paper: pp. 450-454. Clean and fine. First printing of one of the papers which marks the beginning of Mendeléeff's aeronautical recherches to which he turned after his discovery of the periodic table. These researches were stimulated by his interest in the gas-laws of Boyle-Mariotte and Gay-Lussac and aimed at establishing the ontology of the ether.

(Paris, Mallet-Bachelier), 1860. 4to. No wrappers. In: "Comptes Rendus Hebdomadaires des Séances de L'Academie des Sciences", Tome 50, No 1. Pp. (13-) 59. (Entire issue offered). Mendeléef's paper: pp. 52-54. First appearance of an importent paper in which he "recognized a relation between the molecular cohesion of a liquid and its chemical reactivity. The esterification of an alcohol by an acid occurs in such a way that the sum of the molecular cohesions of the products of the reaction (ester + water) is much greater than that of reacting substances, an idea later applied to the influence of solvents"(Partington "A History of Chemistry", vol. 4, p. 893).

Paris, Gauthier-Villars, 1878. 4to. No wrappers. In: "Comptes Rendus Hebdomadaires des Séances de L'Academie des Sciences", Tome 51, No 3. Pp. (73-) 108. (Entire issue offered). Mendeleev's paper: pp. 97-99. First appearance of an importent paper in which Mendeleev investigates the relation between capillarity, or cohesion and temperature. He became convinced that the force of chemical affinity was identical to the force of cohesion.

(Paris, Gauthier-Villars), 1875. 4to. No wrappers. In: "Comptes Rendus Hebdomadaires des Séances de L'Academie des Sciences", Tome 81, No 23 a. 24. Pp. (1065-) 1222. (2 entire issues offered). Mendeleev's paper: pp. 1094-1096 a. 1182-1186. Clean and fine. First printing of a paper which marks the beginning of Mendeléeff's aeronautical recherches to which he turned after his discovery of the periodic table, giving a general form to his experiments on the temperature of the upper layers of the atmosphere.

Paris, Gauthier-Villars, 1875. 4to. No wrappers. In: "Comptes Rendus Hebdomadaires des Séances de L'Academie des Sciences", Tome 81, No 21. Pp. (909-) 992. With titlepage to vol. 81. Mendelejeff's paper: pp. 969-972. Titlepage lightly browned and with a punched stamp in lower margin. Otherwise clean and fine. First apperance of this importent paper which established that Gallium is identical with Eka-aluminum (the missing element between Aluminum and Indium) in Mendelejeff's periodic table. The properties of the new element corresponded well with those predicted. A bitter contorversy was raised between the discoverer of Gallium, Lecog de Boisbaudran and Mendelejeff. "The discovery of the three elements predicted by Mendeleev was, however, of decisive importance in the acceptance of his law. In 1875 Lecoq de Boisbaudran, knowing nothing of Mendeleev?s work, discovered by spectroscopic methods a new metal, which he named gallium. Both in the nature of its discovery and in a number of its properties gallium coincided with Mendeleev?s prediction for eka-aluminum, but its specific weight at first seemed to be less than predicted. Hearing of the discovery, Mendeleev sent to France "Zametka po povodu otkrytia gallia" (the paper offered) ("Note on the Occasion of the Discovery of Gallium"), in which he insisted that gallium was in fact his eka-aluminum. Although Lecoq de Boisbaudran objected to this interpretation, he made a second determination of the specific weight of gallium and confirmed that such was indeed the case. From that moment the periodic law was no longer a mere hypothesis, and the scientific world was astounded to note that Mendeleev, the theorist, had seen the properties of a new element more clearly than the chemist who had empirically discovered it. From this time, too, Mendeleev?s work came to be more widely known"(DSB).Parkinson Breakthroughs" 1875 C.

St.-Pétersbourg [Saint Petersburg], Eggers [for the Académie Impériale des Sciences de St.-Pétersbourg], 1861. Folio (32.8 x 24.4 cm). 6 pp. (numbered 245-250). Original printed wrappers. = Dmitri Ivanovich Mendeleev (1834-1907) was a Russian chemist known for formulating the periodic law and creating a version of the periodic table of elements. He used the periodic law not only to correct the then-accepted properties of some known elements, such as the valence and atomic weight of uranium, but also to predict the properties of three elements that were yet to be discovered (germanium, gallium and scandium). Between 1859 and 1861, he worked on the capillarity of liquids and the workings of the spectroscope in Heidelberg. Later in 1861, he published a textbook named Organic Chemistry. This won him the Demidov Prize of the Petersburg Academy of Sciences. a little-known fact is that Mendeleev, during the same period, made a first attempt to a chemical classification. On 2 August 1861 he read before the Imperial Academy of Sciences of Saint Petersburg an essay on a theory of the limits of organic combinations (this paper), noting homologies in the properties of series of organic molecules of similar built. Evidently, his developing sense of organizing chemical elements according to analogies in their intrinsic properties started here, only later to become expanded to the periodic table of chemical elements which made him world-famous. Uncut. Contemporary label of the French bookseller Chevreuil in Paris mounted on the front wrapper, top edge; some minor, marginal damp-staining and spotting, otherwise very good, as issued.

S.-Peterburg, 1880. 8vo. Contemporary half calf. Capitals and corners with wear. Some crayon-underlinings and some brownspotting. (2),160" 80 pp + 12 folded plates. Scarce first edition of this fundamental guide of aeronautics, which constitutes one of the most important works in aviation history. The work formed the basis for Russian aeronautics, influencing the likes of Tsiolkovsky. The great Russian chemist D.I. Mendeleev suspected that, in the highest levels of the Earth atmosphere, the Ether might exist at natural vacuum. It is this thought that sparks his growing interest in meteorology and aeronautics, which begins to take form in the 1870'ies. For Mendeleev aerodynamics and aeromechanics was inseparably linked to hydrodynamics and hydromechanics, and also to the theory of shipbuilding. He viewed these as belonging to one general problem, which he called media resistance and which he summarized and described in detail in his important work "On the Resistance of Liquids and Air flying"/" About Liquids Resistance and Aeronautics", 1880 [i.e. the present work]. A great part of the work is dedicated to the questions of hydrodynamic theory and contains important analyses of the development of liquids resistance theory from Newton till Froud. Pinpointing the weakest points of the hitherto most important theories, he concluded that even the most important scientists were not able to understand the not examined resistance and thus that theoretical studies alone will not be able to resolve the issue, but require conjoint regular tests of models in hydrodynamic laboratories. Thus, Mendeleev initiated a new school, namely that of experimental hydrodynamics of ships, and the present work became one of the fundamental guides for work in shipbuilding, aeronautics, airplane construction, and ballistics. It greatly influenced the likes of Tsiolkovsky and Zhukovsky and thus formed the basis of Russian aeronautics. It is in the present work that Mendeleev first describes his famous aerostat, the first attempt by Russian. His aerostat was supposed to be able to reach the stratosphere, but the project was never realized. His interest in aerostatics, however, as presented in the present work, led to his famous baloon ride in 1887, to watch the full solar eclipse."The earliest attempts to establish the theoretical possibility of air flight were made by Leonardo da Vinci, whose observations of bird flight inspired him to conceive the ideas of flying on heavier-than-air machines, of the helicopter, and of the parachute. But credit for the further development of his theoretical ideas and their realization belongs to the Russians. A large contribution to the development of aviation was made by D.I. Mendeleev, who conceived of a stratospheric balloon and devised plans for its construction in 1875. The first foreigner to construct a stratospheric balloon was Picard in 1931. In 1887, Mendeleev ascended 3,350 meters in the balloon to observe a solar eclipse. Mendeleev defined the future significance of aviation with great foresight. His "On the Resistance of Liquids and Aeronautics" (1880) served as one of the fundamental guides for work in shipbuilding, aeronautics, airplane construction, and ballistics." (Geldern & Stites edt.: Mass Culture in Soviet Russia, p. 480).