chiefly+(other)

BLESSED

alya, almárëa (prosperous, rich, abundant), herenya (wealthy, fortunate, rich), manaquenta or manquenta, also aman ("blessed, free from evil" – Aman was "chiefly used as the name of the land where the Valar dwelt" [WJ:399], and as an adjective “blessed” the word may add an adjectival ending: amanya, VT49:41). Aman is the apparent Quenya equivalent of “the Blessed Realm” (allative Amanna is attested, VT49:26). The word calambar, apparently literally *“light-fated”, also seems to mean “blessed” (VT49:41). Cf. also BLESSED BEING Manwë (name of the King of the Valar). Alya, almárëa, and herenya are adjectives that may also have worldly connontations, apparently often used with reference to one who is "blessed" with material possessions or simply has good luck; on the other hand, the forms derived from the root man- primarily describe something free from evil: Cf. mána "blessed" in Fíriel's Song (referring to the Valar) and the alternative form manna in VT43:19 [cf. VT45:32] (in VT45 referring to the Virgin Mary; the form mána may be preferred for clarity, since manna is apparently also the question-word "whither?", "where to?") The forms manaquenta or manquenta also include the man- root, but it is combined with a derivative (passive participle?) of the verbal stem quet- "say, speak", these forms seemingly referring to someone who is "blessed" in the sense that people speak well of this person (a third form from the same source, manque, is possibly incomplete: read manquenta?) (VT44:10-11) The most purely "spiritual" term is possibly the word aistana, used for "blessed" in Tolkien's translation of the Hail Mary, where this word refers to the Virgin (VT43:27-28, 30). Aistana is apparently not an independent adjective (like alya, mána etc.), but rather the passive participle of a verb \#aista- "bless"; see above concerning its precise application. BLESSEDNESS vald- (so in LT1:272; nom. sg. must be either *val or *valdë) (happiness; but since this word comes from early material where it was intended to be related to Valar "Happy/Blessed Ones", its conceptual validity may be doubted because Tolkien later reinterpreted Valar as "the Powers" and dropped the earlier etymology). BLESSING (a boon, a good or fortunate thing), see BOON. "BLESSINGS", BLESSEDNESS, BLISS almië, almarë; FINAL BLISS manar, mandë (doom, final end, fate, fortune) –LotR:989 cf Letters:308; GAL, KHER, Letters:283, LT1:272, MAN/MANAD, VT43:19, 27-28, 30

Davy, Sir Humphry

SUBJECT AREA: Chemical technology, Mining and extraction technology

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b. 17 December 1778 Penzance, Cornwall, England

d. 29 May 1829 Geneva, Switzerland

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English chemist, discoverer of the alkali and alkaline earth metals and the halogens, inventor of the miner's safety lamp.

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Educated at the Latin School at Penzance and from 1792 at Truro Grammar School, Davy was apprenticed to a surgeon in Penzance. In 1797 he began to teach himself chemistry by reading, among other works, Lavoisier's elementary treatise on chemistry. In 1798 Dr Thomas Beddoes of Bristol engaged him as assistant in setting up his Pneumatic Institution to pioneer the medical application of the newly discovered gases, especially oxygen.

In 1799 he discovered the anaesthetic properties of nitrous oxide, discovered not long before by the chemist Joseph Priestley. He also noted its intoxicating qualities, on account of which it was dubbed "laughing-gas". Two years later Count Rumford, founder of the Royal Institution in 1800, appointed Davy Assistant Lecturer, and the following year Professor. His lecturing ability soon began to attract large audiences, making science both popular and fashionable.

Davy was stimulated by Volta's invention of the voltaic pile, or electric battery, to construct one for himself in 1800. That enabled him to embark on the researches into electrochemistry by which is chiefly known. In 1807 he tried decomposing caustic soda and caustic potash, hitherto regarded as elements, by electrolysis and obtained the metals sodium and potassium. He went on to discover the metals barium, strontium, calcium and magnesium by the same means. Next, he turned his attention to chlorine, which was then regarded as an oxide in accordance with Lavoisier's theory that oxygen was the essential component of acids; Davy failed to decompose it, however, even with the aid of electricity and concluded that it was an element, thus disproving Lavoisier's view of the nature of acids. In 1812 Davy published his Elements of Chemical Philosophy, in which he presented his chemical ideas without, however, committing himself to the atomic theory, recently advanced by John Dalton.

In 1813 Davy engaged Faraday as Assistant, perhaps his greatest service to science. In April 1815 Davy was asked to assist in the development of a miner's lamp which could be safely used in a firedamp (methane) laden atmosphere. The "Davy lamp", which emerged in January 1816, had its flame completely surrounded by a fine wire mesh; George Stephenson's lamp, based on a similar principle, had been introduced into the Northumberland pits several months earlier, and a bitter controversy as to priority of invention ensued, but it was Davy who was awarded the prize for inventing a successful safety lamp.

In 1824 Davy was the first to suggest the possibility of conferring cathodic protection to the copper bottoms of naval vessels by the use of sacrificial electrodes. Zinc and iron were found to be equally effective in inhibiting corrosion, although the scheme was later abandoned when it was found that ships protected in this way were rapidly fouled by weeds and barnacles.

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Principal Honours and Distinctions

Knighted 1812. FRS 1803; President, Royal Society 1820. Royal Society Copley Medal 1805.

Bibliography

1812, Elements of Chemical Philosophy.

1839–40, The Collected Works of Sir Humphry Davy, 9 vols, ed. John Davy, London.

Further Reading

J.Davy, 1836, Memoirs of the Life of Sir Humphry Davy, London (a classic biography). J.A.Paris, 1831, The Life of Sir Humphry Davy, London (a classic biography). H.Hartley, 1967, Humphry Davy, London (a more recent biography).

J.Z.Fullmer, 1969, Cambridge, Mass, (a bibliography of Davy's works).

ASD

Goulding, John

SUBJECT AREA: Textiles

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b. 1791 Massachusetts, USA d. 1877

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American inventor of an early form of condenser carding machine.

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The condenser method of spinning was developed chiefly by manufacturers and machine makers in eastern Massachusetts between 1824 and 1826. John Goulding, a machinist from Dedham in Massachusetts, combined the ring doffer, patented by Ezekiel Hale in 1825, and the revolving twist tube, patented by George Danforth in 1824; with the addition of twisting keys in the tubes, the carded woollen sliver could be divided and then completely and continuously twisted. He divided the carded web longitudinally with the ring doffer and twisted these strips to consolidate them into slubbings. The dividing was carried out by covering the periphery of the doffer cylinder with separate rings of card clothing and spacing these rings apart by rings of leather, so that instead of width-way detached strips leaving the card, the strips were continuous and did not require piecing. The strips were passed through rotating tubes and wound on bobbins, and although the twist was false it sufficed to compress the fibres together ready for spinning. Goulding patented his invention in both Britain and the USA in 1826, but while his condensers were very successful and within twenty years had been adopted by a high proportion of woollen mills in America, they were not adopted in Britain until much later. Goulding also worked on other improvements to woollen machinery: he developed friction drums, on which the spools of roving from the condenser cards were placed to help transform the woollen jenny into the woollen mule or jack.

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Bibliography

1826, British patent no. 5,355 (condenser carding machine).

Further Reading

D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830s, Oxford (provides a good explanation of the development of the condenser card).

W.English, 1969, The Textile Industry, London (a brief account).

C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (a brief account).

RLH

Lumière, Auguste

SUBJECT AREA: Photography, film and optics

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b. 19 October 1862 Besançon, France

d. 10 April 1954 Lyon, France

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French scientist and inventor.

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Auguste and his brother Louis Lumière (b. 5 October 1864 Besançon, France; d. 6 June 1948 Bandol, France) developed the photographic plate-making business founded by their father, Charles Antoine Lumière, at Lyons, extending production to roll-film manufacture in 1887. In the summer of 1894 their father brought to the factory a piece of Edison kinetoscope film, and said that they should produce films for the French owners of the new moving-picture machine. To do this, of course, a camera was needed; Louis was chiefly responsible for the design, which used an intermittent claw for driving the film, inspired by a sewing-machine mechanism. The machine was patented on 13 February 1895, and it was shown on 22 March 1895 at the Société d'Encouragement pour l'In-dustrie Nationale in Paris, with a projected film showing workers leaving the Lyons factory. Further demonstrations followed at the Sorbonne, and in Lyons during the Congrès des Sociétés de Photographie in June 1895. The Lumières filmed the delegates returning from an excursion, and showed the film to the Congrès the next day. To bring the Cinématographe, as it was called, to the public, the basement of the Grand Café in the Boulevard des Capuchines in Paris was rented, and on Saturday 28 December 1895 the first regular presentations of projected pictures to a paying public took place. The half-hour shows were an immediate success, and in a few months Lumière Cinématographes were seen throughout the world.

The other principal area of achievement by the Lumière brothers was colour photography. They took up Lippman's method of interference colour photography, developing special grainless emulsions, and early in 1893 demonstrated their results by lighting them with an arc lamp and projecting them on to a screen. In 1895 they patented a method of subtractive colour photography involving printing the colour separations on bichromated gelatine glue sheets, which were then dyed and assembled in register, on paper for prints or bound between glass for transparencies. Their most successful colour process was based upon the colour-mosaic principle. In 1904 they described a process in which microscopic grains of potato starch, dyed red, green and blue, were scattered on a freshly varnished glass plate. When dried the mosaic was coated with varnish and then with a panchromatic emulsion. The plate was exposed with the mosaic towards the lens, and after reversal processing a colour transparency was produced. The process was launched commercially in 1907 under the name Autochrome; it was the first fully practical single-plate colour process to reach the public, remaining on the market until the 1930s, when it was followed by a film version using the same principle.

Auguste and Louis received the Progress Medal of the Royal Photographic Society in 1909 for their work in colour photography. Auguste was also much involved in biological science and, having founded the Clinique Auguste Lumière, spent many of his later years working in the physiological laboratory.

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Further Reading

Guy Borgé, 1980, Prestige de la photographie, Nos. 8, 9 and 10, Paris. Brian Coe, 1978, Colour Photography: The First Hundred Years, London ——1981, The History of Movie Photography, London.

Jacques Deslandes, 1966, Histoire comparée du cinéma, Vol. I, Paris. Gert Koshofer, 1981, Farbfotografie, Vol. I, Munich.

BC

aircraft engine emission

1. выхлопы двигателей летательных аппаратов

 

выхлопы двигателей летательных аппаратов
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]

EN

aircraft engine emission
The formation and discharge of gaseous and particulate pollutants into the environment, especially the stratosphere, chiefly from airplanes, helicopters and other high-altitude aircrafts. (Source: MHE)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]

Тематики

• охрана окружающей среды

EN

• aircraft engine emission

DE

• Flugzeugemission

FR

• émissions des moteurs d'avions