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1 Applied Laboratory Methods
Biochemistry: ALMУниверсальный русско-английский словарь > Applied Laboratory Methods
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2 ALM
1) Общая лексика: Asset and liability management2) Военный термин: advanced list of materials, air-launched missile3) Шутливое выражение: Another Loose Microchip4) Железнодорожный термин: Arkansas Louisiana and Mississippi Railroad Company5) Юридический термин: American Lawyer Media6) Грубое выражение: Another Lonely Man7) Сокращение: Air Loadmaster (UK Royal Air Force)8) Университет: A Laboratory Mistake9) Вычислительная техника: Asynchronous Line Module, Asynchronous Line Multiplexer, Application / Appware Loadable Module (Novell, Netware), звуковой сигнал предупреждения (об опасности)10) Биохимия: Applied Laboratory Methods11) Транспорт: Always Luggage Missing12) Образование: Adults Learning Mathematics13) Сетевые технологии: AppWare Loadable Module, Application Loadable Module14) Макаров: administration and logistics manager15) Расширение файла: All Luggage Missing16) США: Arkansas, Louisiana, And Mississippi17) Общественная организация: Arts League of Michigan18) Аэропорты: Alamogordo, New Mexico USA19) Программное обеспечение: Application Lifecycle Management -
3 Alm
1) Общая лексика: Asset and liability management2) Военный термин: advanced list of materials, air-launched missile3) Шутливое выражение: Another Loose Microchip4) Железнодорожный термин: Arkansas Louisiana and Mississippi Railroad Company5) Юридический термин: American Lawyer Media6) Грубое выражение: Another Lonely Man7) Сокращение: Air Loadmaster (UK Royal Air Force)8) Университет: A Laboratory Mistake9) Вычислительная техника: Asynchronous Line Module, Asynchronous Line Multiplexer, Application / Appware Loadable Module (Novell, Netware), звуковой сигнал предупреждения (об опасности)10) Биохимия: Applied Laboratory Methods11) Транспорт: Always Luggage Missing12) Образование: Adults Learning Mathematics13) Сетевые технологии: AppWare Loadable Module, Application Loadable Module14) Макаров: administration and logistics manager15) Расширение файла: All Luggage Missing16) США: Arkansas, Louisiana, And Mississippi17) Общественная организация: Arts League of Michigan18) Аэропорты: Alamogordo, New Mexico USA19) Программное обеспечение: Application Lifecycle Management -
4 alm
1) Общая лексика: Asset and liability management2) Военный термин: advanced list of materials, air-launched missile3) Шутливое выражение: Another Loose Microchip4) Железнодорожный термин: Arkansas Louisiana and Mississippi Railroad Company5) Юридический термин: American Lawyer Media6) Грубое выражение: Another Lonely Man7) Сокращение: Air Loadmaster (UK Royal Air Force)8) Университет: A Laboratory Mistake9) Вычислительная техника: Asynchronous Line Module, Asynchronous Line Multiplexer, Application / Appware Loadable Module (Novell, Netware), звуковой сигнал предупреждения (об опасности)10) Биохимия: Applied Laboratory Methods11) Транспорт: Always Luggage Missing12) Образование: Adults Learning Mathematics13) Сетевые технологии: AppWare Loadable Module, Application Loadable Module14) Макаров: administration and logistics manager15) Расширение файла: All Luggage Missing16) США: Arkansas, Louisiana, And Mississippi17) Общественная организация: Arts League of Michigan18) Аэропорты: Alamogordo, New Mexico USA19) Программное обеспечение: Application Lifecycle Management -
5 Maxwell, James Clerk
[br]b. 13 June 1831 Edinburgh, Scotlandd. 5 November 1879 Cambridge, England[br]Scottish physicist who formulated the unified theory of electromagnetism, the kinetic theory of gases and a theory of colour.[br]Maxwell attended school at the Edinburgh Academy and at the age of 16 went on to study at Edinburgh University. In 1850 he entered Trinity College, Cambridge, where he graduated four years later as Second Wrangler with the award of the Smith's Prize. Two years later he was appointed Professor at Marischal College, Aberdeen, where he married the Principal's daughter. In 1860 he moved to King's College London, but on the death of his father five years later, Maxwell returned to the family home in Scotland, where he continued his researches as far as the life of a gentleman farmer allowed. This rural existence was interrupted in 1874 when he was persuaded to accept the chair of Cavendish Professor of Experimental Physics at Cambridge. Unfortunately, in 1879 he contracted the cancer that brought his brilliant career to an untimely end. While at Cambridge, Maxwell founded the Cavendish Laboratory for research in physics. A succession of distinguished physicists headed the laboratory, making it one of the world's great centres for notable discoveries in physics.During the mid-1850s, Maxwell worked towards a theory to explain electrical and magnetic phenomena in mathematical terms, culminating in 1864 with the formulation of the fundamental equations of electromagnetism (Maxwell's equations). These equations also described the propagation of light, for he had shown that light consists of transverse electromagnetic waves in a hypothetical medium, the "ether". This great synthesis of theories uniting a wide range of phenomena is worthy to set beside those of Sir Isaac Newton and Einstein. Like all such syntheses, it led on to further discoveries. Maxwell himself had suggested that light represented only a small part of the spectrum of electromagnetic waves, and in 1888 Hertz confirmed the discovery of another small part of the spectrum, radio waves, with momentous implications for the development of telecommunication technology. Maxwell contributed to the kinetic theory of gases, which by then were viewed as consisting of a mass of randomly moving molecules colliding with each other and with the walls of the containing vessel. From 1869 Maxwell applied statistical methods to describe the molecular motion in mathematical terms. This led to a greater understanding of the behaviour of gases, with important consequences for the chemical industry.Of more direct technological application was Maxwell's work on colour vision, begun in 1849, showing that all colours could be derived from the three primary colours, red, yellow and blue. This enabled him in 1861 to produce the first colour photograph, of a tartan. Maxwell's discoveries about colour vision were quickly taken up and led to the development of colour printing and photography.[br]BibliographyMost of his technical papers are reprinted in The Scientific Papers of J.Clerk Maxwell, 1890, ed. W.D.Niven, Cambridge, 2 vols; reprinted 1952, New York.Maxwell published several books, including Theory of Heat, 1870, London (1894, 11th edn, with notes by Lord Rayleigh) and Theory of Electricity and Magnetism, 1873, Oxford (1891, ed. J.J.Thomson, 3rd edn).Further ReadingL.Campbell and W.Garnett, 1882, The Life of James Clerk Maxwell, London (the standard biography).J.J.Thomson (ed.), 1931, James Clerk Maxwell 1831–1931, Cambridge. J.G.Crowther, 1932, British Scientists of the Nineteenth Century, London.LRD -
6 Bunsen, Robert Wilhelm
SUBJECT AREA: Chemical technology[br]b. 31 March 1811 Göttingen, Germanyd. 16 August 1899 Heidelberg, Germany[br]German chemist, pioneer of chemical spectroscopy.[br]Bunsen's father was Librarian and Professor of Linguistics at Göttingen University and Bunsen himself studied chemistry there. Obtaining his doctorate at the age of only 19, he travelled widely, meeting some of the leading chemists of the day and visiting many engineering works. On his return he held various academic posts, finally as Professor of Chemistry at Heidelberg in 1852, a post he held until his retirement in 1889.During 1837–41 Bunsen studied a series of compounds shown to contain the cacodyl (CH3)2As-group or radical. The elucidation of the structure of these compounds gave support to the radical theory in organic chemistry and earned him fame, but it also cost him the sight of an eye and other ill effects resulting from these dangerous and evil-smelling substances. With the chemist Gustav Robert Kirchhoff (1824–87), Bunsen pioneered the use of spectroscopy in chemical analysis from 1859, and with its aid he discovered the elements caesium and rubidium. He developed the Bunsen cell, a zinc-carbon primary cell, with which he isolated a number of alkali and other metals by electrodeposition from solution or electrolysis of fused chlorides.Bunsen's main work was in chemical analysis, in the course of which he devised some important laboratory equipment, such as a filter pump. The celebrated Bunsen gas burner was probably devised by his technician Peter Desdega. During 1838–44 Bunsen applied his methods of gas analysis to the study of the gases produced by blast furnaces for the production of cast iron. He demonstrated that no less than 80 per cent of the heat was lost during smelting, and that valuable gaseous by-products, such as ammonia, were also lost. Lyon Playfair in England was working along similar lines, and in 1848 the two men issued a paper, "On the gases evolved from iron furnaces", to draw attention to these drawbacks.[br]Bibliography1904, Bunsen's collected papers were published in 3 vols, Leipzig.Further ReadingG.Lockemann, 1949, Robert Wilhelm Bunsen: Lebensbild eines deutschen Forschers, Stuttgart.T.Curtin, 1961, biog. account, in E.Farber (ed.), Great Chemists, New York, pp. 575–81. Henry E.Roscoe, 1900, "Bunsen memorial lecture, 29th March 1900", Journal of theChemical Society 77:511–54.LRD -
7 получать ... распространение
Получать (большее) распространение-- Of the many methods applied to nuclei measurements two optical techniques have become more favored for use in the laboratory environment - light scattering and holography.Русско-английский научно-технический словарь переводчика > получать ... распространение
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8 time
(a) (in general) temps mtime frame délai m;time limit délai;∎ the work must be completed within the time limit le travail doit être terminé avant la date limite;time management gestion f du temps de travail;time to market temps m d'accès au marché;time and methods study étude des temps et des méthodes;time and motion consultant expert m en productivité, spécialiste m f de l'organisation scientifique du travail;time and motion studies organisation f scientifique du travail, OST f;time and motion study étude de productivité (qui porte sur l'organisation scientifique du travail); MARKETING time pricing fixation f des prix en fonction du moment;COMPUTING time sharing partage m de temps;time slot créneau m horaire;STOCK EXCHANGE time value valeur f temporelle(b) (by clock) heure f;∎ time of arrival/departure heure d'arrivée/de départtime card feuille f de présence;time clock pointeuse f;time difference décalage m horaire;time rate rémunération f au temps passé;time sheet fiche f horaire;time work travail m à l'heure;STOCK EXCHANGE time bargain marché m à terme;FINANCE time bill traite f à terme;American time deposit dépôt m à terme;time draft traite à terme;time loan emprunt m à terme;INSURANCE time policy police f à terme;time value valeur f temporelle∎ we pay time and a half on weekends nous payons les heures du week-end une fois et demie le tarif normal;∎ overtime is paid at double time les heures supplémentaires sont payées ou comptées doubleAvnet Applied Computing (AAC) … officially opened a new engineering laboratory built to provide a resource-rich environment where original equipment manufacturer customers and AAC engineers can work side-by-side to cut the time to market of their designs.
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9 Crookes, Sir William
SUBJECT AREA: Electricity[br]b. 17 June 1832 London, Englandd. 4 April 1919 London, England[br]English chemist and physicist who carried out studies of electrical discharges and cathode rays in rarefied gases, leading to the development of the cathode ray tube; discoverer of the element thallium and the principle of the Crookes radiometer.[br]Crookes entered the Royal College of Chemistry at the age of 15, and from 1850 to 1854 held the appointment of Assistant at the college. In 1854 he became Superintendent of the Meteorological Department at the Radcliffe Observatory in Oxford. He moved to a post at the College of Science in Chester the following year. Soon after this he inherited a large fortune and set up his own private laboratory in London. There he studied the nature of electrical discharges in gases at low pressure and discovered the dark space (later named after him) that surrounds the negative electrode, or cathode. He also established that the rays produced in the process (subsequently shown by J.J.Thompson to be a stream of electrons) not only travelled in straight lines, but were also capable of producing heat and/or light upon impact with suitable anode materials. Using a variety of new methods to investigate these "cathode" rays, he applied them to the spectral analysis of compounds of selenium and, as a result, in 1861 he discovered the element thallium, finally establishing its atomic weight in 1873. Following his discovery of thallium, he became involved in two main lines of research: the properties of rarified gases, and the investigation of the elements of the "rare earths". It was also during these experiments that he discovered the principle of the Crookes radiometer, a device in which light is converted into rotational motion and which used to be found frequently in the shop windows of English opticians. Also among the fruits of this work were the Crookes tubes and the development of spectacle lenses with differential ranges of radiational absorption. In the 1870s he became interested in spiritualism and acquired a reputation for his studies of psychic phenomena, but at the turn of the century he returned to traditional scientific investigations. In 1892 he wrote about the possibility of wireless telegraphy. His work in the field of radioactivity led to the invention of the spinthariscope, an early type of detector of alpha particles. In 1900 he undertook investigations into uranium which led to the study of scintillation, an important tool in the study of radioactivity.While the theoretical basis of his work has not stood the test of time, his material discoveries, observations and investigations of new facts formed a basis on which others such as J.J. Thomson were to develop subatomic theory. His later involvement in the investigation of spiritualism led to much criticism, but could be justified on the basis of a belief in the duty to investigate all phenomena.[br]Principal Honours and DistinctionsKnighted 1897. Order of Merit 1910. FRS 1863. President, Royal Society 1913–15. Honorary LLD Birmingham. Honorary DSc Oxon, Cambridge, Sheffield, Durham, Ireland and Cape of Good Hope.Bibliography1874, On Attraction and Repulsion Resulting from Radiation.1874, "Researches in the phenomenon of spiritualism", Society of Metaphysics; reprinted in facsimile, 1986.For many years he was also Proprietor and Editor of Chemical News.Further ReadingE.E.Fournier D'Albe, 1923, Life of Sir William Crookes. Who Was Who II, 1916–28, London: A. \& C. Black. T.I.Williams, 1969, A Biographical Dictionary of Scientists. See also Braun, Karl Ferdinand.KF / MG
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