Each of these molecules

восстанавливать до первоначального вида

♦

Each of these molecules is restored to its original form.

восстанавливать до первоначального вида

♦

Each of these molecules is restored to its original form.

возвращаться к

. вновь приобретать

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We revert (or return) to our previous analogy.

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β-sulphur turns back to its α-form if sublimed at abt. 320 K.

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Then the material reverts to the metallic state.

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The plant is now back to normal operation.

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The crystal regains its original dimensions.

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Each of these molecules is restored to its original form.

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We revert to the ideal-gas expression.

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. вновь приобретать

•

We revert (or return) to our previous analogy.

•

β-sulphur turns back to its α-form if sublimed at abt. 320 K.

•

Then the material reverts to the metallic state.

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The plant is now back to normal operation.

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The crystal regains its original dimensions.

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Each of these molecules is restored to its original form.

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We revert to the ideal-gas expression.

никак нельзя отличить от

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These molecules can in no way be distinguished from each other.

охотно реагировать с

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Formaldehyde molecules react readily (or avidly, or briskly) with each other.

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These bonds are susceptible to reaction with electron-deficient reagents.

сближаться

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The molecules approach each other.

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As a result, these two elements are brought into proximity.

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Before two HC1 molecules can approach closely enough for interaction to be sufficiently strong,...

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The ends of a six-carbon chain approach each other (or draw close together).

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The two points and F' come ( close) together as the solvent rate approaches its minimum value.

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The atoms are brought closer together.

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The peaks come closer and closer together.

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The particles draw (or move) closer together.

приписывать

. объяснять; относить за счёт

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Historians trace both ideas to ancient Greeks.

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Perhaps the ancients knew more about astronomy than we give them credit for.

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He was the first to study the gas systematically and so he gets credit for its discovery.

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We ascribe to r(β) and s(α) the values determined at points and , respectively.

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The boundary values are assigned to the term uv.

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The amber was assigned a negative charge.

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Not long ago these diseases were accredited to our dizzy pace of living.

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Anderson ascribes this disagreement to the oversimplified model.

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The increased boron content may be attributed (or ascribed) to the dissolution of the samples.

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A large number of early investigators are credited with the invention of the mercury thermometer.

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If we put it down to chance ( случайности),...

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The same type of structure can be assigned to many other molecules with unsaturated six-member rings.

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The elementary particles can be classified by assigning quantum numbers to each of them.

происходить

. наблюдаться

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Anaplastic cells are derived from adult, differentiated cells.

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This change comes about by virtue of the force acting on...

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Such explosions come ( about) (or occur) each 100 years.

II

. иметь место; наблюдаться

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No major breakthrough has come about (разг.).

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Most of the world's volcanic activity is found near the boundaries of...

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We know from experience that this does not happen.

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This process has been going on for 3 billion years.

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The change from melt to crystalline rock happens (or occurs) rapidly.

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Here, fluvial denudation has been in progress for long periods of time.

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Expansion of the clay mass results when more water penetrates...

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The Mediterranean Sea was the site of extensive evaporite depositions ( B Средиземном море происходили...).

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Processes of fluvial denudation are at work from the very beginning.

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Such an event will never come to pass.

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Two processes operate simultaneously.

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Every living cell is a seat of numerous metabolic reactions.

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Combustion will occur (or proceed) at any pressure if a suitable catalyst is added.

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If a leak occurs urgent measures should be taken.

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Under these conditions the transformation of heat energy into other forms of energy takes place.

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The 1930s saw a marked spurt in the technological applications of catalysts.

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The past 20 years have witnessed an amazing increase in the number of molecules detected.

состоять из

. из которого состоит; представлять собой

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In each year, there are about 31,557,000 seconds.

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Pink ruby is comprised of A1₂O₃ doped with 0.005% Cr₂O₃.

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The rest of the plant involves (or consists of) typical mass transfer equipment.

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Production of aluminum metal involves two steps.

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Carbohydrate analysis involves separation of the carbohydrate mixture, identification of the individual carbohydrates, and estimation of their quantities.

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The measuring system is built up from a number of standard units.

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The element is composed (or is made up, or consists) of equal numbers of protons and neutrons.

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Most of the common gaseous elements are constituted by diatomic molecules.

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The rock is made up of the calcite shells of microorganisms.

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The machine is made up of two subassemblies - a drive unit and...

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This class is made up almost entirely of metals.

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The machine is comprised of three automatic drill units, two lead-screw tapping units, and a rotary-indexing turntable.

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The stress tensor comprises the mechanical part and the viscous part.

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The attachment incorporates a microscope and a protractor.

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The hologram comprises (or consists of) 16 subholograms.

II

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These graphs fall into two groups.

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The satellite's atmosphere is 90 percent methane.

Maxwell, James Clerk

SUBJECT AREA: Chemical technology, Electricity

[br]

b. 13 June 1831 Edinburgh, Scotland

d. 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]

Bibliography

Most 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 Reading

L.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