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1 atomic physicist
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2 physicist
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3 физик-атомщик
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4 Atomphysiker
* * *Atom|phy|si|ker(in)m(f)nuclear physicist* * *Atom·phy·si·ker(in)m(f) nuclear physicist* * *der nuclear or atomic physicist* * ** * *der nuclear or atomic physicist -
5 Atomphysikerin
f1. atomic physicist [female]2. nuclear physicist [female] -
6 атомник
чatomic scientist; atomic physicist -
7 kernfysicus
1 nuclear/atomic physicist -
8 атомен
atomic, atom (attr.); atomicalатомна бомба an atom/atomic bomb, an A-bombатомна война atomic warfareатомна физика nuclear physics; nucleonicsатомна енергия atomic/nuclear energyатомен физик a nuclear physicistатомно ядро an atomic nucleusатомен заряд an atomic warheadатомно тегло/число atomic weight/number* * *а̀томен,прил., -на, -но, -ни atomic, atom (attr.); atomical, nuclear; \атоменен заряд atomic warhead; \атоменен реактор fission reactor; \атоменен физик nuclear physicist; \атоменен център nuclear research centre; \атоменна бомба atom/atomic bomb, A-bomb; fission bomb; \атоменна война atomic warfare; \атоменна физика nuclear physics; \атоменна централа nuclear power station; \атоменно ядро atomic nucleus.* * *1. atomic, atom (attr.);atomical 2. АТОМЕН заряд an atomic warhead 3. АТОМЕН физик a nuclear physicist 4. атомна бомба an atom/atomic bomb, an A-bomb 5. атомна война atomic warfare 6. атомна енергия atomic/nuclear energy 7. атомна физика nuclear physics;nucleonics 8. атомно тегло/ число atomic weight/number 9. атомно ядро an atomic nucleus -
9 Fermi, Enrico
[br]b. 29 September 1901 Rome, Italyd. 28 November 1954 Chicago, USA[br]Italian nuclear physicist.[br]Fermi was one of the most versatile of twentieth-century physicists, one of the few to excel in both theory and experiment. His greatest theoretical achievements lay in the field of statistics and his theory of beta decay. His statistics, parallel to but independent of Dirac, were the key to the modern theory of metals and the statistical modds of the atomic nucleus. On the experimental side, his most notable discoveries were artificial radioactivity produced by neutron bombardment and the realization of a controlled nuclear chain reaction, in the world's first nuclear reactor.Fermi received a conventional education with a chemical bias, but reached proficiency in mathematics and physics largely through his own reading. He studied at Pisa University, where he taught himself modern physics and then travelled to extend his knowledge, spending time with Max Born at Göttingen. On his return to Italy, he secured posts in Florence and, in 1927, in Rome, where he obtained the first Italian Chair in Theoretical Physics, a subject in which Italy had so far lagged behind. He helped to bring about a rebirth of physics in Italy and devoted himself to the application of statistics to his model of the atom. For this work, Fermi was awarded the Nobel Prize in Physics in 1938, but in December of that year, finding the Fascist regime uncongenial, he transferred to the USA and Columbia University. The news that nuclear fission had been achieved broke shortly before the Second World War erupted and it stimulated Fermi to consider this a way of generating secondary nuclear emission and the initiation of chain reactions. His experiments in this direction led first to the discovery of slow neutrons.Fermi's work assumed a more practical aspect when he was invited to join the Manhattan Project for the construction of the first atomic bomb. His small-scale work at Columbia became large-scale at Chicago University. This culminated on 2 December 1942 when the first controlled nuclear reaction took place at Stagg Field, Chicago, an historic event indeed. Later, Fermi spent most of the period from September 1944 to early 1945 at Los Alamos, New Mexico, taking part in the preparations for the first test explosion of the atomic bomb on 16 July 1945. President Truman invited Fermi to serve on his Committee to advise him on the use of the bomb. Then Chicago University established an Institute for Nuclear Studies and offered Fermi a professorship, which he took up early in 1946, spending the rest of his relatively short life there.[br]Principal Honours and DistinctionsNobel Prize for Physics 1938.Bibliography1962–5, Collected Papers, ed. E.Segrè et al., 2 vols, Chicago (includes a biographical introduction and bibliography).Further ReadingL.Fermi, 1954, Atoms in the Family, Chicago (a personal account by his wife).E.Segrè, 1970, Enrico Fermi, Physicist, Chicago (deals with the more scientific aspects of his life).LRD -
10 Essen, Louis
SUBJECT AREA: Horology[br]b. 6 September 1908 Nottingham, England[br]English physicist who produced the first practical caesium atomic clock, which was later used to define the second.[br]Louis Essen joined the National Physical Laboratory (NPL) at Teddington in 1927 after graduating from London University. He spent his whole working life at the NPL and retired in 1972; his research there was recognized by the award of a DSc in 1948. At NPL he joined a team working on the development of frequency standards using quartz crystals and he designed a very successful quartz oscillator, which became known as the "Essen ring". He was also involved with radio frequency oscillators. His expertise in these fields was to play a crucial role in the development of the caesium clock. The idea of an atomic clock had been proposed by I.I.Rabbi in 1945, and an instrument was constructed shortly afterwards at the National Bureau of Standards in the USA. However, this device never realized the full potential of the concept, and after seeing it on a visit to the USA Essen was convinced that a more successful instrument could be built at Teddington. Assisted by J.V.L.Parry, he commenced work in the spring of 1953 and by June 1955 the clock was working reliably, with an accuracy that was equivalent to one second in three hundred years. This was significantly more accurate than the astronomical observations that were used at that time to determine the second: in 1967 the second was redefined in terms of the value for the frequency of vibration of caesium atoms that had been obtained with this clock.[br]Principal Honours and DistinctionsFRS 1960. Clockmakers' Company Tompion Gold Medal 1957. Physical Society C.V.Boys Prize 1957. USSR Academy of Science Popov Gold Medal 1959.Bibliography1957, with J.V.L.Parry, "The caesium resonator as a standard of frequency and time", Philosophical Transactions of the Royal Society (Series A) 25:45–69 (the first comprehensive description of the caesium clock).Further ReadingP.Forman, 1985, "Atomichron: the atomic clock from concept to commercial product", Proceedings of the IEEE 75:1,181–204 (an authoritative critical review of the development of the atomic clock).N.Cessons (ed.), 1992, The Making of the Modern World, London: Science Museum, pp.190–1 (contains a short account).See also: Marrison, Warren AlvinDV -
11 Atomphysik
f nuclear physics Pl. (V. im Sg.)* * *Atom|phy|sikfatomic or nuclear physics sing* * *Atom·phy·sikf nuclear physics + sing vb* * ** * ** * *die nuclear or atomic physics sing., no art* * *f.nuclear physics n. -
12 Tuve, Merle Antony
[br]b. 27 June 1901 Canton, South Dakota, USAd. 20 May 1982 Bethesda, Maryland, USA[br]American physicist and geophysicist who developed radio exploration of the ionosphere and made contributions to seismology and atomic physics.[br]After BS and AM degrees from the University of Minnesota, Tuve gained a PhD in physics from Johns Hopkins University in 1926. He then joined the Department of Terrestrial Magnetism at the Carnegie Institute, Washington, DC, where with Breit he established by experiment the existence and characteristics of the ionosphere. He also studied gamma and beta rays, artificial radioactivity and atomic transmutation, verified the existence of the neutron and measured nuclear binding forces. During the Second World War he performed military research, producing a proximity fuse for use against the VI flying bomb. He returned to Carnegie in 1946 as Director of the Department of Terrestrial Magnetism, where he remained until 1966, making many contributions to the study of the earth and space.[br]Principal Honours and DistinctionsAmerican Association for the Advancement of Science Prize for atomic and nuclear research 1931. National Academy of Science 1946. Research Corporation Award 1947. Comstock Prize 1948. National Academy of Science Barnard Medal 1955. Presidential Medal of Merit and Distinguished Service Member of the Carnegie Institute 1966.Bibliography1926, with G.Breit, "A test of the existence of the conducting layer", Physical Review 28:554 (gives an account of the early ionospheric studies).See also: Appleton, Sir Edward VictorKF -
13 Randall, Sir John Turton
SUBJECT AREA: Medical technology[br]b. 23 March 1905 Newton-le-Willows, Lancashire, Englandd. 16 June 1984 Edinburgh, Scotland[br]English physicist and biophysicist, primarily known for the development, with Boot of the cavity magnetron.[br]Following secondary education at Ashton-inMakerfield Grammar School, Randall entered Manchester University to read physics, gaining a first class BSc in 1925 and his MSc in 1926. From 1926 to 1937 he was a research physicist at the General Electric Company (GEC) laboratories, where he worked on luminescent powders, following which he became Warren Research Fellow of the Royal Society at Birmingham University, studying electronic processes in luminescent solids. With the outbreak of the Second World War he became an honorary member of the university staff and transferred to a group working on the development of centrimetric radar. With Boot he was responsible for the development of the cavity magnetron, which had a major impact on the development of radar.When Birmingham resumed its atomic research programme in 1943, Randall became a temporary lecturer at the Cavendish Laboratory in Cambridge. The following year he was appointed Professor of Natural Philosophy at the University of St Andrews, but in 1946 he moved again to the Wheatstone Chair of Physics at King's College, London. There his developing interest in biophysical research led to the setting up of a multi-disciplinary group in 1951 to study connective tissues and other biological components, and in 1950– 5 he was joint Editor of Progress in Biophysics. From 1961 until his retirement in 1970 he was Professor of Biophysics at King's College and for most of that time he was also Chairman of the School of Biological Sciences. In addition, for many years he was honorary Director of the Medical Research Council Biophysics Research Unit.After he retired he returned to Edinburgh and continued to study biological problems in the university zoology laboratory.[br]Principal Honours and DistinctionsKnighted 1962. FRS 1946. FRS Edinburgh 1972. DSc Manchester 1938. Royal Society of Arts Thomas Gray Memorial Prize 1943. Royal Society Hughes Medal 1946. Franklin Institute John Price Wetherill Medal 1958. City of Pennsylvania John Scott Award 1959. (All jointly with Boot for the cavity magnetron.)Bibliography1934, Diffraction of X-Rays by Amorphous Solids, Liquids \& Gases (describes his early work).1953, editor, Nature \& Structure of Collagen.1976, with H.Boot, "Historical notes on the cavity magnetron", Transactions of the Institute of Electrical and Electronics Engineers ED-23: 724 (gives an account of the cavity-magnetron development at Birmingham).Further ReadingM.H.F.Wilkins, "John Turton Randall"—Bio-graphical Memoirs of Fellows of the Royal Society, London: Royal Society.KFBiographical history of technology > Randall, Sir John Turton
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14 atomforsker
subst. nuclear physicist, atomic researcher subst. nuclear scientist, atomic scientist -
15 Appleton, Sir Edward Victor
[br]b. 6 September 1892 Bradford, Englandd. 21 April 1965 Edinburgh, Scotland[br]English physicist awarded the Nobel Prize for Physics for his discovery of the ionospheric layer, named after him, which is an efficient reflector of short radio waves, thereby making possible long-distance radio communication.[br]After early ambitions to become a professional cricketer, Appleton went to St John's College, Cambridge, where he studied under J.J.Thompson and Ernest Rutherford. His academic career interrupted by the First World War, he served as a captain in the Royal Engineers, carrying out investigations into the propagation and fading of radio signals. After the war he joined the Cavendish Laboratory, Cambridge, as a demonstrator in 1920, and in 1924 he moved to King's College, London, as Wheatstone Professor of Physics.In the following decade he contributed to developments in valve oscillators (in particular, the "squegging" oscillator, which formed the basis of the first hard-valve time-base) and gained international recognition for research into electromagnetic-wave propagation. His most important contribution was to confirm the existence of a conducting ionospheric layer in the upper atmosphere capable of reflecting radio waves, which had been predicted almost simultaneously by Heaviside and Kennelly in 1902. This he did by persuading the BBC in 1924 to vary the frequency of their Bournemouth transmitter, and he then measured the signal received at Cambridge. By comparing the direct and reflected rays and the daily variation he was able to deduce that the Kennelly- Heaviside (the so-called E-layer) was at a height of about 60 miles (97 km) above the earth and that there was a further layer (the Appleton or F-layer) at about 150 miles (240 km), the latter being an efficient reflector of the shorter radio waves that penetrated the lower layers. During the period 1927–32 and aided by Hartree, he established a magneto-ionic theory to explain the existence of the ionosphere. He was instrumental in obtaining agreement for international co-operation for ionospheric and other measurements in the form of the Second Polar Year (1932–3) and, much later, the International Geophysical Year (1957–8). For all this work, which made it possible to forecast the optimum frequencies for long-distance short-wave communication as a function of the location of transmitter and receiver and of the time of day and year, in 1947 he was awarded the Nobel Prize for Physics.He returned to Cambridge as Jacksonian Professor of Natural Philosophy in 1939, and with M.F. Barnett he investigated the possible use of radio waves for radio-location of aircraft. In 1939 he became Secretary of the Government Department of Scientific and Industrial Research, a post he held for ten years. During the Second World War he contributed to the development of both radar and the atomic bomb, and subsequently served on government committees concerned with the use of atomic energy (which led to the establishment of Harwell) and with scientific staff.[br]Principal Honours and DistinctionsKnighted (KCB 1941, GBE 1946). Nobel Prize for Physics 1947. FRS 1927. Vice- President, American Institute of Electrical Engineers 1932. Royal Society Hughes Medal 1933. Institute of Electrical Engineers Faraday Medal 1946. Vice-Chancellor, Edinburgh University 1947. Institution of Civil Engineers Ewing Medal 1949. Royal Medallist 1950. Institute of Electrical and Electronics Engineers Medal of Honour 1962. President, British Association 1953. President, Radio Industry Council 1955–7. Légion d'honneur. LLD University of St Andrews 1947.Bibliography1925, joint paper with Barnett, Nature 115:333 (reports Appleton's studies of the ionosphere).1928, "Some notes of wireless methods of investigating the electrical structure of the upper atmosphere", Proceedings of the Physical Society 41(Part III):43. 1932, Thermionic Vacuum Tubes and Their Applications (his work on valves).1947, "The investigation and forecasting of ionospheric conditions", Journal of theInstitution of Electrical Engineers 94, Part IIIA: 186 (a review of British work on the exploration of the ionosphere).with J.F.Herd \& R.A.Watson-Watt, British patent no. 235,254 (squegging oscillator).Further ReadingWho Was Who, 1961–70 1972, VI, London: A. \& C.Black (for fuller details of honours). R.Clark, 1971, Sir Edward Appleton, Pergamon (biography).J.Jewkes, D.Sawers \& R.Stillerman, 1958, The Sources of Invention.KFBiographical history of technology > Appleton, Sir Edward Victor
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16 исследовать
•Now let us use the methods of quantum mechanics to attack the hydrogen-atom problem.
•The physicist can probe an atomic nucleus whenever laboratory apparatus is available.
•This enabled the scientists to probe the floor of every ocean except the Arctic.
Русско-английский научно-технический словарь переводчика > исследовать
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17 נילס הנריק דויד בוהר
Niels Henrik David Bohr (1885-1962), Danish physicist who studied and researched the atomic structure, Nobel prize winner in physics in 1922, father of Aage Niels Bohr -
18 nuclear
'nju:kliə1) (using atomic energy: a nuclear power station; nuclear weapons.) nuclear2) (of a nucleus.) nuclearnuclear adj nuclear
nuclear adjetivo nuclear
nuclear adjetivo nuclear ' nuclear' also found in these entries: Spanish: arma - bomba - central - energía - desnuclearizar - física - funcionamiento - guerra - lluvia - potencia - reactor - vertedero English: meltdown - nuclear - nuclear energy - nuclear war - power - warhead - core - deterrent - - free - holocaust - reactortr['njʊːklɪəSMALLr/SMALL]1 nuclear\SMALLIDIOMATIC EXPRESSION/SMALLnuclear bomb bomba nuclearnuclear capability potencial nombre masculino nuclearnuclear capacity capacidad nombre femenino nuclearnuclear disarmament desarme nombre masculino nuclearnuclear energy energía nuclearnuclear facility planta de energía nuclearnuclear family familia nuclearnuclear fission fisión nombre femenino nuclearnuclear fusion fusión nombre femenino nuclearnuclear physics física nuclearnuclear power energía nuclearnuclear power station central nombre femenino nuclearnuclear reaction reacción nombre femenino nuclearnuclear reactor reactor nombre masculino nuclearnuclear war guerra nuclearnuclear waste residuos nuclearesnuclear weapon arma nuclearnuclear winter invierno nuclearnuclear ['nu:kliər, 'nju:-] adj: nuclearadj.• nuclear adj.'nuːkliər, 'njuːkliə(r)adjective nuclearnuclear power — energía f nuclear
['njuːklɪǝ(r)]nuclear power station — central f nuclear
1.ADJ (Phys, Mil) nuclear2.CPDnuclear age N — era f nuclear
nuclear bomb N — bomba f nuclear
nuclear capability N — capacidad f nuclear
nuclear deterrent N — fuerza f disuasiva nuclear
nuclear disarmament N — desarme m nuclear
nuclear energy N — energía f nuclear
nuclear family N — familia f nuclear
nuclear fission N — fisión f nuclear
nuclear fuel N — combustible m nuclear
nuclear fusion N — fusión f nuclear
Nuclear Non-Proliferation Treaty N — Tratado m de No Proliferación Nuclear
nuclear physicist N — físico(-a) m / f nuclear
nuclear physics N — física f nuclear
nuclear power N — energía f nuclear
nuclear power station, nuclear (power) plant N — central f nuclear
nuclear reaction N — reacción f nuclear
nuclear reactor N — reactor m nuclear
nuclear scientist N — científico(-a) m / f nuclear
nuclear shelter N — refugio m antinuclear
nuclear submarine N — submarino m nuclear
nuclear test N — prueba f nuclear
nuclear testing N — pruebas fpl nucleares
nuclear war N — guerra f nuclear
nuclear waste N — desechos mpl nucleares
nuclear weapon N — arma f nuclear
nuclear winter N — invierno m nuclear
* * *['nuːkliər, 'njuːkliə(r)]adjective nuclearnuclear power — energía f nuclear
nuclear power station — central f nuclear
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19 исследовать
•Now let us use the methods of quantum mechanics to attack the hydrogen-atom problem.
•The physicist can probe an atomic nucleus whenever laboratory apparatus is available.
•This enabled the scientists to probe the floor of every ocean except the Arctic.
* * *Исследовать (влияние)-- Parametric values of the coefficients have been investigated for their influence on the stability of the rotor motion. Исследовать -- to examine, to explore, to study, to investigate, to addressThis investigation examined the relationships between hardness and wear for eight cast alloys.Исследовать на-- Selected specimens were examined metallographically for corrosion.Русско-английский научно-технический словарь переводчика > исследовать
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20 Boot, Henry Albert Howard
[br]b. 29 July 1917 Birmingham, Englandd. 8 February 1983 Cambridge, England[br]English physicist who, with John Randall, invented the cavity magnetron used in radar systems.[br]After secondary education at King Edward School, Birmingham, Boot studied physics at Birmingham University, obtaining his BSc in 1938 and PhD in 1941. With the outbreak of the Second World War, he became involved with Randall and others in the development of a source of microwave power suitable for use in radar transmitters. Following unsuccessful attempts to use klystrons, they turned to investigation of the magnetron, and by adding cavity resonators they obtained useful power on 21 February 1940 at a wavelength of 9.8 cm. By May a cavity magnetron radar system had been constructed at TRE, Swanage, and in September submarine periscopes were detected at a range of 7 miles (11 km).In 1943 the physics department at Birmingham resumed its research in atomic physics and Boot moved to BTH at Rugby to continue development of magnetrons, but in 1945 he returned to Birmingham as Nuffield Research Fellow and helped construct the cyclotron there. Three years later he took up a post as a Principal Scientific Officer (PSO) at the Services Electronic Research Laboratories at Baldock, Hertfordshire, becoming a Senior PSO in 1954. He remained there until his retirement in 1977, variously carrying out research on microwaves, magnetrons, plasma physics and lasers.[br]Principal Honours and DistinctionsRoyal Society of Arts Thomas Gray Memorial Prize 1943. Royal Commission Inventors Award 1946. Franklin Institute John Price Wetherill Medal 1958. City of Pennsylvania John Scott Award 1959. (All jointly with Randall.)Bibliography1976, with J.T.Randall, "Historical notes on the cavity magnetron", Transactions of the Institute of Electrical and Electronics Engineers ED-23: 724 (provides an account of their development of the cavity magnetron).Further ReadingE.H.Dix and W.H.Aldous, 1966, Microwave Valves.KFBiographical history of technology > Boot, Henry Albert Howard
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