develop the subject

to develop the subject

1) to develop the subject (the plot, the idea) развивать тему (сюжет, мысль)

2) развивать проблему

subject

['sʌbdʒɪkt]

n

1) тема, предмет разговора, вопрос, сюжет

The subject is not very well dealt with in his last book. — В его последней книге этот вопрос плохо освещен.

He is off the subject. — Он говорит не на тему.

The subject drifted away into another channel. — Тема разговора незаметно перешла в другую область.

- ridiculos subject

- interesting subject
- dellicate subject
- stock subjects
- examination subjects
- thesis subject
- key subject
- off-the-record subject
- suggestive subject
- subject picture
- subject of common interest
- hackneyed subjects of polities
- subject for congratulation
- subject of praise
- safe subject for conversation
- subject of the lecture
- subject of a book
- subjects of rural life
- subject of graduate study
- pictures of sacred subjects
- all conceivable subjects of interest to students
- no restriction as to subject
- approach the subject from a practical point of view
- avoid the subject
- bar the subject
- bring up the subject in the course of conversation
- broach the subject in the course of conversation
- change the subject
- choose a subject for discussion
- classify books by subjects
- classify the subjects you are interested in
- close the subject
- consider the next subjects
- cover the whole subject
- dismiss the subject summarily
- divert the subject into another channel

- drop the subject

- express one's opinion on the subject

- find information on the subject
- get to the main subject
- handle the subject in a masterly way
- have strong views on the subject
- introduce a sore subject
- keep to the subject
- lead smb on to the subject
- open the subject
- pursue the subject further
- return to our subject
- speak on the subject
- study the subject thoroughly
- take smb too far from the subject
- treat the subject at great length
- touch upon the subject
- turn the subject over in one's mind
- view the subject from different angles
- wander from the subject
- work on this subject
- every time the subject comes up

2) проблема, вопрос

We have different opinions (strong views) on the subject. — У нас разные мнения (твердые взгляды) по этому вопросу.

He has a different approach to the subject. — У него иной подход к данной проблеме.

- serious subject

- fundamental subject

- a delicate subject

- tender

- domestic subjects
- interesting subjects
- academic subjects
- controversial subjects
- subject under consideration
- smb's approach to the subject
- break up the subject into sections
- bring the conversation round to the subject
- deal with new subjects

- develop the subject

- discuss the subject in all its aspects

- go deep into the subject
- handle the subject delicately
- illustrate the subject with appropriate quotations
- investigate the subject
- keep off the subject
- know one's subject
- narrow down one's subject to two problems
- start the subject
- state the subject
- submit up the subject to the judgement of scholars
- survey the subject
- treat the subject technically
- view the subject from a practical point of view
- weigh the subject dispassionately

3) предмет, учебная дисциплина

What subjects are you studying? — Какие вы проходите предметы?

What subjects does he teach? — Какие он преподает предметы?

I'll have to read on the subject. — Мне надо готовиться к экзамену по этому предмету.

- compulsary subjects

- difficult subjects
- school subjects
- liberal arts subjects
- secondary subjects
- smb's favourite subject at school
- subject of serious study
- subject of interest for students
- be taught as a separate subject
- fail in a subject
- learn the subject with ease
- master a subject
- pass a subject
- read on the subject
- take the subject seriously
- teach a subject

4) подданный (государства, короля)

- British subject

- subject of the crown
- subject to the king

5) грам. подлежащее

- Complex Subject

- impersonal subject
- subject of the sentence
- subject precedes the predicate in a regular sentence

develop

[dɪ'veləp]

v

1) развивать, разрабатывать, совершенствовать

- develop agriculture

- develop one's fingers
- develop one's memory
- develop the subject

2) развиваться

The events were developing very fast. — События развивались очень быстро.

- plot develops slowly

3) проявлять

- develop a photo

develop

1. I

abs

1) his character is developing его характер формируется; our friendship has developed наша дружба окрепла

2) new facts (some additional details, certain circumstances, etc.) have developed обнаружились /выяснились/ новые факты и т. д.; а new feature of the case developed a) обнаружилась /возникла/ еще одна сторона дела; б) дело приняло новый оборот; а rash (new symptoms, a fever, etc.) developed появилась сыпь и т. д., an ulcer developed образовалась язва

2. II

develop in some manner

1) develop harmoniously (gradually, physically, morally. culturally,.etc.) гармонично и т. д. развиваться; the boy has developed intellectually мальчик интеллектуально развился; the plot (the story, the play. etc.) develops rapidly сюжет и т. д. развивается /развёртывается/ стремительно; develop in every way (a lot, by leaps and bounds, etc.) развиваться всеми способами или во всех отношениях и т. д.

2) develop gradually (partially, etc.) проявляться постепенно и т. д.; this type of film develops quickly этот вид пленки проявляется быстро; these photographs haven't developed very well эти фотографии плохо вышли /проявились/

3. III

develop smth.

1) develop the country's industry (a district, a coal area, etc.) развивать промышленность страны и т. д., develop the natural resources of a country разрабатывать природные богатства страны; we shall develop this mine будем разрабатывать /осваивать/ эту шахту: they are developing a new manufacturing process они разрабатывают новый технологический процесс: he developed his business он расширил свое дело

2) develop different muscles (the strength of one's fingers. healthy bodies, one's memory, one's brain, the mind, etc.) укреплять /развивать, тренировать разные мышцы и т. д.

3) develop exotic flowers (hot house tomatoes, subtropical fruit, etc.) выращивать экзотические цветы и т. д.; develop new forms of the plant выводить новые сорта растения; heat and moisture develop seed тепло и влага способствуют росту /развитию/ семян; different conditions have developed different forms of life разные условия привели к появлению разных форм жизни; this engine develops a lot of heat Этот мотор сильно нагревается

4) develop new facts (new features, certain details, etc.) обнаруживать /вскрывать/ новые факты и т. д.; the inquiry developed unforeseen aspects of the case при расследовании обнаружились неожиданные стороны этого дела

5) he developed symptoms of consumption (of a fever, of a cough. of a tumour, etc.) у него появились симптомы чахотки и т. д.', he seems to be developing an illness он. кажется, заболевает; the child developed whooping cough у ребенка начался коклюш

6) develop a subject (the plot of a play, an argument, a plan, an idea. a line of thought, etc.) разрабатывать /развивать/ тему и т. д; you should develop this theme вам следует развить эту тему

7) develop one's films (the plates, a photograph, etc.) проявлять [отснятую] пленку и т. д.

4. IV

develop smth. in some manner develop this idea (this subject, the theme, etc.) a little more fully развить /разработать/ эту мысль и т. д. полнее

5. XI

1) be developed in some manner be rather poorly developed быть плохо развитым, отставать в развитии; he is well developed mentally умственно он хорошо развит; be developed at /in/ some place in this school children's gifts are developed в этой школе обращают особое внимание на развитие природных талантов у детей

2) be developed somewhere this plate may be developed at home эту пластинку можно проявлять в домашних условиях

6. XVI

develop from /out of/ smth. develop from a seed (from a simpler machine, from an acorn, etc.) развиваться из зерна и т. д., this town developed out of a fishing village этот город вырос из /на месте/ рыбацкого поселка; develop Into smth. develop into plants (into beautiful butterflies, etc.) превращаться в растения и т. д, their acquaintance has developed into friendship их знакомство перешло в дружбу; develop Into smb. the boy developed into a good man из мальчика вырос хороший человек; - in some place develop in the author's mind созревать /зреть/ в уме автора

7. XXI1

1) develop smth. for smth. develop a gift (a taste, a habit, etc.) for smth. развивать талант и т. д. к чему-л.

2) develop smth. in some time I shall develop the film in twenty minutes я проявлю эту пленку за двадцать минут

develop

/di'veləp/ * ngoại động từ - trình bày, bày tỏ, thuyết minh (luận điểm, vấn đề...) =to develop+ tỏ, thuyết minh (luận điểm, vấn đề...) =to one's views on a subject+ trình bày quan điểm về một vấn đề - phát triển, mở mang, mở rộng, khuếch trương, làm cho phát đạt =to develop industry+ phát triển công nghiệp =to develop an industrial area+ mở rộng khu công nghiệp =to develop one's mind+ phát triển trí tuệ =to develop one's body+ phát triển cơ thể, làm cho cơ thể nở nang - khai thác =to develop resources+ khai thác tài nguyên - nhiễm, tiêm nhiễm (thói quen...); ngày càng bộc lộ rõ, ngày càng phát huy (khả năng, khuynh hướng...) =to develop a bad habit+ nhiễm thói xấu =to develop a gilf for machematics+ ngày càng bộc lộ rõ khiếu về toán - (nhiếp ảnh) rửa (phim ảnh) - (quân sự) triển khai, mở =to develop an attack+ mở một cuộc tấn công - (toán học) khai triển * nội động từ - tỏ rõ ra, bộc lộ ra, biểu lộ ra - phát triển, mở mang, nảy nở =seeda develop into plants+ hạt giống phát triển thành cây con - tiến triển =the story developed into good ending+ câu chuyện tiến triển đến một kết thúc tốt đẹp - hiện (ảnh)

Strutt, Jedediah

SUBJECT AREA: Textiles

[br]

b. 26 July 1726 South Normanton, near Alfreton, Derbyshire, England

d. 7 May 1797 Derby, England

[br]

English inventor of a machine for making ribbed knitting.

[br]

Jedediah Strutt was the second of three sons of William, a small farmer and maltster at South Normanton, near Alfreton, Derbyshire, where the only industry was a little framework knitting. At the age of 14 Jedediah was apprenticed to Ralph Massey, a wheelwright near Derby, and lodged with the Woollats, whose daughter Elizabeth he later married in 1755. He moved to Leicester and in 1754 started farming at Blackwell, where an uncle had died and left him the stock on his farm. It was here that he made his knitting invention.

William Lee's knitting machine remained in virtually the same form as he left it until the middle of the eighteenth century. The knitting industry moved away from London into the Midlands and in 1730 a Nottingham workman, using Indian spun yarn, produced the first pair of cotton hose ever made by mechanical means. This industry developed quickly and by 1750 was providing employment for 1,200 frameworkers using both wool and cotton in the Nottingham and Derby areas. It was against this background that Jedediah Strutt obtained patents for his Derby rib machine in 1758 and 1759.

The machine was a highly ingenious mechanism, which when placed in front of an ordinary stocking frame enabled the fashionable ribbed stockings to be made by machine instead of by hand. To develop this invention, he formed a partnership first with his brother-in-law, William Woollat, and two leading Derby hosiers, John Bloodworth and Thomas Stamford. This partnership was dissolved in 1762 and another was formed with Woollat and the Nottingham hosier Samuel Need. Strutt's invention was followed by a succession of innovations which enabled framework knitters to produce almost every kind of mesh on their machines. In 1764 the stocking frame was adapted to the making of eyelet holes, and this later lead to the production of lace. In 1767 velvet was made on these frames, and two years later brocade. In this way Strutt's original invention opened up a new era for knitting. Although all these later improvements were not his, he was able to make a fortune from his invention. In 1762 he was made a freeman of Nottingham, but by then he was living in Derby. His business at Derby was concerned mainly with silk hose and he had a silk mill there.

It was partly his need for cotton yarn and partly his wealth which led him into partnership with Richard Arkwright, John Smalley and David Thornley to exploit Arkwright's patent for spinning cotton by rollers. Together with Samuel Need, they financed the Arkwright partnership in 1770 to develop the horse-powered mill in Nottingham and then the water-powered mill at Cromford. Strutt gave advice to Arkwright about improving the machinery and helped to hold the partnership together when Arkwright fell out with his first partners. Strutt was also involved, in London, where he had a house, with the parliamentary proceedings over the passing of the Calico Act in 1774, which opened up the trade in British-manufactured all-cotton cloth.

In 1776 Strutt financed the construction of his own mill at Helper, about seven miles (11 km) further down the Derwent valley below Cromford. This was followed by another at Milford, a little lower on the river. Strutt was also a partner with Arkwright and others in the mill at Birkacre, near Chorley in Lancashire. The Strutt mills were developed into large complexes for cotton spinning and many experiments were later carried out in them, both in textile machinery and in fireproof construction for the mills themselves. They were also important training schools for engineers.

Elizabeth Strutt died in 1774 and Jedediah never married again. The family seem to have lived frugally in spite of their wealth, probably influenced by their Nonconformist background. He had built a house near the mills at Milford, but it was in his Derby house that Jedediah died in 1797. By the time of his death, his son William had long been involved with the business and became a more important cotton spinner than Jedediah.

[br]

Bibliography

1758. British patent no. 722 (Derby rib machine). 1759. British patent no. 734 (Derby rib machine).

Further Reading

For the involvement of Strutt in Arkwright's spinning ventures, there are two books, the earlier of which is R.S.Fitton and A.P.Wadsworth, 1958, The Strutts and the Arkwrights, 1758–1830, Manchester, which has most of the details about Strutt's life. This has been followed by R.S.Fitton, 1989, The Arkwrights, Spinners of Fortune, Manchester.

R.L.Hills, 1970, Power in the Industrial Revolution, Manchester (for a general background to the textile industry of the period).

W.Felkin, 1967, History of the Machine-wrought Hosiery and Lace Manufactures, reprint, Newton Abbot (orig. pub. 1867) (covers Strutt's knitting inventions).

RLH

Demenÿ, Georges

SUBJECT AREA: Photography, film and optics

[br]

b. 1850 Douai, France d. 1917

[br]

French chronophotographer.

[br]

As a young man Georges Demenÿ was a pioneer of physical education in France, and this led him to contact the physiologist Professor Marey in 1880. Marey had made a special study of animal movement, and Demenÿ hoped to work with him on research into physiological problems related to gymnastics. He joined Marey the following year, and when in 1882 the Physiological Station was set up near Paris to develop sequence photography for the study of movement. Demenÿ was made Head of the laboratory. He worked with the multiple-image fixed-plate cameras, and was chiefly responsible for the analysis of the records, having considerable mathematical and graphical ability. He also appeared as the subject in a number of the sequences. When in 1888 Marey began the development of a film camera, Demenÿ was involved in its design and operation. He became interested in the possibility of using animated sequence photographs as an aid to teaching of the deaf. He made close-up records of himself speaking short phrases, "Je vous aime" and "Vive la France" for example, which were published in such journals as Paris Photographe and La Nature in 1891 and 1892. To present these in motion, he devised the Phonoscope, which he patented on 3 March 1892. The series of photographs were mounted around the circumference of a disc and viewed through a counter-rotating slotted disc. The moving images could be viewed directly, or projected onto a screen. La Nature reported tests he had made in which deaf lip readers could interpret accurately what was being said. On 20 December 1892 Demenÿ formed a company, Société Générale du Phonoscope, to exploit his invention, hoping that "speaking portraits" might replace family-album pictures. This commercial activity led to a rift between Marey and Demenÿ in July 1893. Deprived of access to the film cameras, Demenÿ developed designs of his own, patenting new camera models in France on 10 October 1893 and 27 July 1894. The design covered by the latter had been included in English and German patents filed in December 1893, and was to be of some significance in the early development of cinematography. It was for an intermittent movement of the film, which used an eccentrically mounted blade or roller that, as it rotated, bore on the film, pulling down the length of one frame. As the blade moved away, the film loop so formed was taken up by the rotation of the take-up reel. This "beater" movement was employed extensively in the early years of cinematography, being effective yet inexpensive. It was first employed in the Chronophotographe apparatus marketed by Gaumont, to whom Demenÿ had licensed the patent rights, from the autumn of 1896. Demenÿ's work provided a link between the scientific purposes of sequence photography— chronophotography—and the introduction of commercial cinematography.

[br]

Further Reading

J.Deslandes, 1966, Histoire comparée du cinéma, Vol. I, Paris. B.Coe, 1992, Muybridge and the Chronophotographers, London.

BC

Gabor, Dennis (Dénes)

SUBJECT AREA: Photography, film and optics

[br]

b. 5 June 1900 Budapest, Hungary

d. 9 February 1979 London, England

[br]

Hungarian (naturalized British) physicist, inventor of holography.

[br]

Gabor became interested in physics at an early age. Called up for military service in 1918, he was soon released when the First World War came to an end. He then began a mechanical engineering course at the Budapest Technical University, but a further order to register for military service prompted him to flee in 1920 to Germany, where he completed his studies at Berlin Technical University. He was awarded a Diploma in Engineering in 1924 and a Doctorate in Electrical Engineering in 1927. He then went on to work in the physics laboratory of Siemens \& Halske. He returned to Hungary in 1933 and developed a new kind of fluorescent lamp called the plasma lamp. Failing to find a market for this device, Gabor made the decision to abandon his homeland and emigrate to England. There he joined British Thompson-Houston (BTH) in 1934 and married a colleague from the company in 1936. Gabor was also unsuccessful in his attempts to develop the plasma lamp in England, and by 1937 he had begun to work in the field of electron optics. His work was interrupted by the outbreak of war in 1939, although as he was not yet a British subject he was barred from making any significant contribution to the British war effort. It was only when the war was near its end that he was able to return to electron optics and begin the work that led to the invention of holography. The theory was developed during 1947 and 1948; Gabor went on to demonstrate that the theories worked, although it was not until the invention of the laser in 1960 that the full potential of his invention could be appreciated. He coined the term "hologram" from the Greek holos, meaning complete, and gram, meaning written. The three-dimensional images have since found many applications in various fields, including map making, medical imaging, computing, information technology, art and advertising. Gabor left BTH to become an associate professor at the Imperial College of Science and Technology in 1949, a position he held until his retirement in 1967. In 1971 he was awarded the Nobel Prize for Physics for his work on holography.

[br]

Principal Honours and Distinctions

Royal Society Rumford Medal 1968. Franklin Institute Michelson Medal 1968. CBE 1970. Nobel Prize for Physics 1971.

Bibliography

1948. "A new microscopic principle", Nature 161:777 (Gabor's earliest publication on holography).

1949. "Microscopy by reconstructed wavefronts", Proceedings of the Royal Society A197: 454–87.

1951, "Microscopy by reconstructed wavefronts II", Proc. Phys. Soc. B, 64:449–69. 1966, "Holography or the “Whole Picture”", New Scientist 29:74–8 (an interesting account written after laser beams were used to produce optical holograms).

Further Reading

T.E.Allibone, 1980, contribution to Biographical Memoirs of Fellows of the Royal Society 26: 107–47 (a full account of Gabor's life and work).

JW

Stephenson, Robert

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 16 October 1803 Willington Quay, Northumberland, England

d. 12 October 1859 London, England

[br]

English engineer who built the locomotive Rocket and constructed many important early trunk railways.

[br]

Robert Stephenson's father was George Stephenson, who ensured that his son was educated to obtain the theoretical knowledge he lacked himself. In 1821 Robert Stephenson assisted his father in his survey of the Stockton \& Darlington Railway and in 1822 he assisted William James in the first survey of the Liverpool \& Manchester Railway. He then went to Edinburgh University for six months, and the following year Robert Stephenson \& Co. was named after him as Managing Partner when it was formed by himself, his father and others. The firm was to build stationary engines, locomotives and railway rolling stock; in its early years it also built paper-making machinery and did general engineering.

In 1824, however, Robert Stephenson accepted, perhaps in reaction to an excess of parental control, an invitation by a group of London speculators called the Colombian Mining Association to lead an expedition to South America to use steam power to reopen gold and silver mines. He subsequently visited North America before returning to England in 1827 to rejoin his father as an equal and again take charge of Robert Stephenson \& Co. There he set about altering the design of steam locomotives to improve both their riding and their steam-generating capacity. Lancashire Witch, completed in July 1828, was the first locomotive mounted on steel springs and had twin furnace tubes through the boiler to produce a large heating surface. Later that year Robert Stephenson \& Co. supplied the Stockton \& Darlington Railway with a wagon, mounted for the first time on springs and with outside bearings. It was to be the prototype of the standard British railway wagon. Between April and September 1829 Robert Stephenson built, not without difficulty, a multi-tubular boiler, as suggested by Henry Booth to George Stephenson, and incorporated it into the locomotive Rocket which the three men entered in the Liverpool \& Manchester Railway's Rainhill Trials in October. Rocket, was outstandingly successful and demonstrated that the long-distance steam railway was practicable.

Robert Stephenson continued to develop the locomotive. Northumbrian, built in 1830, had for the first time, a smokebox at the front of the boiler and also the firebox built integrally with the rear of the boiler. Then in Planet, built later the same year, he adopted a layout for the working parts used earlier by steam road-coach pioneer Goldsworthy Gurney, placing the cylinders, for the first time, in a nearly horizontal position beneath the smokebox, with the connecting rods driving a cranked axle. He had evolved the definitive form for the steam locomotive.

Also in 1830, Robert Stephenson surveyed the London \& Birmingham Railway, which was authorized by Act of Parliament in 1833. Stephenson became Engineer for construction of the 112-mile (180 km) railway, probably at that date the greatest task ever undertaken in of civil engineering. In this he was greatly assisted by G.P.Bidder, who as a child prodigy had been known as "The Calculating Boy", and the two men were to be associated in many subsequent projects. On the London \& Birmingham Railway there were long and deep cuttings to be excavated and difficult tunnels to be bored, notoriously at Kilsby. The line was opened in 1838.

In 1837 Stephenson provided facilities for W.F. Cooke to make an experimental electrictelegraph installation at London Euston. The directors of the London \& Birmingham Railway company, however, did not accept his recommendation that they should adopt the electric telegraph and it was left to I.K. Brunel to instigate the first permanent installation, alongside the Great Western Railway. After Cooke formed the Electric Telegraph Company, Stephenson became a shareholder and was Chairman during 1857–8.

Earlier, in the 1830s, Robert Stephenson assisted his father in advising on railways in Belgium and came to be increasingly in demand as a consultant. In 1840, however, he was almost ruined financially as a result of the collapse of the Stanhope \& Tyne Rail Road; in return for acting as Engineer-in-Chief he had unwisely accepted shares, with unlimited liability, instead of a fee.

During the late 1840s Stephenson's greatest achievements were the design and construction of four great bridges, as part of railways for which he was responsible. The High Level Bridge over the Tyne at Newcastle and the Royal Border Bridge over the Tweed at Berwick were the links needed to complete the East Coast Route from London to Scotland. For the Chester \& Holyhead Railway to cross the Menai Strait, a bridge with spans as long-as 460 ft (140 m) was needed: Stephenson designed them as wrought-iron tubes of rectangular cross-section, through which the trains would pass, and eventually joined the spans together into a tube 1,511 ft (460 m) long from shore to shore. Extensive testing was done beforehand by shipbuilder William Fairbairn to prove the method, and as a preliminary it was first used for a 400 ft (122 m) span bridge at Conway.

In 1847 Robert Stephenson was elected MP for Whitby, a position he held until his death, and he was one of the exhibition commissioners for the Great Exhibition of 1851. In the early 1850s he was Engineer-in-Chief for the Norwegian Trunk Railway, the first railway in Norway, and he also built the Alexandria \& Cairo Railway, the first railway in Africa. This included two tubular bridges with the railway running on top of the tubes. The railway was extended to Suez in 1858 and for several years provided a link in the route from Britain to India, until superseded by the Suez Canal, which Stephenson had opposed in Parliament. The greatest of all his tubular bridges was the Victoria Bridge across the River St Lawrence at Montreal: after inspecting the site in 1852 he was appointed Engineer-in-Chief for the bridge, which was 1 1/2 miles (2 km) long and was designed in his London offices. Sadly he, like Brunel, died young from self-imposed overwork, before the bridge was completed in 1859.

[br]

Principal Honours and Distinctions

FRS 1849. President, Institution of Mechanical Engineers 1849. President, Institution of Civil Engineers 1856. Order of St Olaf (Norway). Order of Leopold (Belgium). Like his father, Robert Stephenson refused a knighthood.

Further Reading

L.T.C.Rolt, 1960, George and Robert Stephenson, London: Longman (a good modern biography).

J.C.Jeaffreson, 1864, The Life of Robert Stephenson, London: Longman (the standard nine-teenth-century biography).

M.R.Bailey, 1979, "Robert Stephenson \& Co. 1823–1829", Transactions of the Newcomen Society 50 (provides details of the early products of that company).

J.Kieve, 1973, The Electric Telegraph, Newton Abbot: David \& Charles.

See also: Pihl, Carl Abraham; Seguin, Marc

PJGR

Bergius, Friedrich Carl Rudolf

SUBJECT AREA: Chemical technology, Mining and extraction technology

[br]

b. 11 October 1884 Goldschmieden, near Breslau, Germany

d. 31 March Buenos Aires, Argentina

[br]

German chemist who invented the coal-liquefaction process

[br]

After studying chemistry in Breslau and Leipzig and assisting inter alia at the institute of Fritz Haber in Karlsruhe on the catalysis of ammonia under high pressure, in 1909 he went to Hannover to pursue his idea of turning coal into liquid hydrocarbon under high hydrogen pressure (200 atm) and high temperatures (470° C). As experiments with high pressure in chemical processes were still in their initial stages and the Technical University could not support him sufficiently, he set up a private laboratory to develop the methods and to construct the equipment himself. Four years later, in 1913, his process for producing liquid or organic compounds from coal was patented.

The economic aspects of this process were apparent as the demand for fuels and lubricants increased more rapidly than the production of oil, and Bergius's process became even more important after the outbreak of the First World War. The Th. Goldschmidt company of Essen contracted him and tried large-scale production near Mannheim in 1914, but production failed because of the lack of capital and experience to operate with high pressure on an industrial level. Both capital and experience were provided jointly by the BASF company, which produced ammonia at Merseburg, and IG Farben, which took over the Bergius process in 1925, the same year that the synthesis of hydrocarbon had been developed by Fischer-Tropsch. Two years later, at the Leuna works, almost 100,000 tonnes of oil were produced from coal; during the following years, several more hydrogenation plants were to follow, especially in the eastern parts of Germany as well as in the Ruhr area, while the government guaranteed the costs. The Bergius process was extremely important for the supply of fuels to Germany during the Second World War, with the monthly production rate in 1943–4 being more than 700,000 tonnes. However, the plants were mostly destroyed at. the end of the war and were later dismantled.

As a consequence of this success Bergius, who had gained an international reputation, went abroad to work as a consultant to several foreign governments. Experiments aiming to reduce the costs of production are still continued in some countries. By 1925, after he had solved all the principles of his process, he had turned to the production of dextrose by hydrolyzing wood with highly concentrated hydrochloric acid.

[br]

Principal Honours and Distinctions

Nobel Prize 1931. Honorary doctorates, Heidelberg, Harvard and Hannover.

Bibliography

1907, "Über absolute Schwefelsäure als Lösungsmittel", unpublished thesis, Weida. 1913, Die Anwendung hoher Drucke bei chemischen Vorgängen und eine Nachbildung

des Entstehungsprozesses der Steinkohle, Halle. 1913, DRP no. 301, 231 (coal-liquefaction process).

1925, "Verflüssigung der Kohle", Zeitschrift des Vereins Deutscher Ingenieure, 69:1313–20, 1359–62.

1933, "Chemische Reaktionen unter hohem Druck", Les Prix Nobel en 1931, Stockholm, pp. 1–37.

Further Reading

Deutsches Bergbau-Museum, 1985, Friedrich Bergius und die Kohleverflüssigung. Stationen einer Entwicklung, Bochum (gives a comprehensive and illustrated description of the man and the technology).

H.Beck, 1982, Friedrich Bergius, ein Erfinderschicksal, Munich: Deutsches Museum (a detailed biographical description).

W.Birkendfeld, 1964, Der synthetische Treibstoff 1933–1945. Ein Beitragzur nationalsozialistischen Wirtschafts-und Rüstungspolitik, Göttingen, Berlin and Frankfurt (describes the economic value of synthetic fuels for the Third Reich).

WK

Burroughs, Michael

SUBJECT AREA: Land transport

[br]

b. mid-twentieth century

[br]

English inventor who developed a new design of racing bicycle.

[br]

His father was a pattern-maker who worked for a time at the de Havilland aircraft factory at Hatfield, Hertfordshire; later he worked in an aeroplane-model shop before turning his attentions to boats and cars. Mike Burroughs left school at the age of 15 to become a self-taught engineer and inventor, regarding himself as an eccentric. Among other things, he invented a machine for packaging coins.

In the 1970s he began to take an interest in bicycles, and he subjected the design and materials of existing machines of conventional design to searching reappraisal. As a result, Burroughs "reinvented" the bicycle, producing an entirely new concept. His father carved the shape of the single-piece frame in wood, from which a carbon-fibre cast was made. The machine proved to be very fast, but neither the sporting nor the industrial world showed much interest in it. Then in 1991 Rudi Terman, of the motor manufacturers Lotus, saw it and was impressed by its potential; he agreed to develop the machine further, but kept the details secret.

The invention was released to an unsuspecting public at the Barcelona Olympic Games of 1992, ridden by Chris Boardman, who won the pursuit gold medal for Great Britain, a triumph for both rider and inventor. In subsequent months, Boardman went on to break several world records on the Lotus bicycle, including on 23 July 1993 the one-hour record with a distance of 52.27 km (32.48 miles).

[br]

Further Reading

C.Boardman and P.Liggett, 1994, The Fastest Man on Two Wheels: In Pursuit of Chris Boardman, London: Boxtree (looks at the revolutionary Lotus racing cycle designed by Burroughs).

IMcN

Congreve, Sir William

SUBJECT AREA: Weapons and armour

[br]

b. 20 May 1772 London, England

d. 16 May 1828 Toulouse, France

[br]

English developer of military rockets.

[br]

He was the eldest son of Lieutenant-General Sir William Congreve, Colonel Commandant of the Royal Artillery, Superintendent of Military Machines and Superintendent Comptroller of the Royal Laboratory at Woolwich, and the daughter of a naval officer. Congreve passed through the Naval Academy at Woolwich and in 1791 was attached to the Royal Laboratory (formerly known as the Woolwich Arsenal), of which his father was then in command. In the 1790s, an Indian prince, Hyder Ali, had had some success against British troops with solid-fuelled rockets, and young Congreve set himself to develop the idea. By about 1806 he had made some 13,000 rockets, each with a range of about 2 km (1¼ miles). The War Office approved their use, and they were first tested in action at sea during the sieges of Boulogne and Copenhagen in 1806 and 1807 respectively. Congreve was commissioned to raise two companies of rocket artillery; in 1813 he commanded one of his rocket companies at the Battle of Leipzig, where although the rockets did little damage to the enemy, the noise and glare of the explosions had a considerable effect in frightening the French and caused great confusion; for this, the Tsar of Russia awarded Congreve a knighthood. The rockets were similarly effective in other battles, including the British attack on Fort McHenry, near Baltimore, in 1814; it is said that this was the inspiration for the lines "the rocket's red glare, the bombs bursting in air" in Francis Scott Key's poem The Star Spangled Banner, which became the United States' national anthem.

Congreve's father died in 1814, and he succeeded him in the baronetcy and as Comptroller of the Royal Laboratory and Superintendent of Military Machines, holding this post until his death. For the last ten years of his life he was Member of Parliament for Plymouth, having previously represented Gatton when elected for that constituency in 1812.

[br]

Principal Honours and Distinctions

FRS 1812.

Further Reading

F.H.Winter, 1990, The First Golden Age of Rocketry: Congreve and Hale Rockets of the Nine-teenth Century, Washington, DC: Smithsonian Institution Press.

IMcN

Cowper-Coles, Sherard Osborn

SUBJECT AREA: Metallurgy

[br]

b. 8 October 1866 East Harting, Sussex, England

d. 9 September 1936

[br]

English inventor of the sherardizing process for metal protection.

[br]

He was the son of Captain Cowper- Coles, Royal Navy, the inventor of the swivelling turret for naval guns. He inherited his father's inventive talents and investigated a variety of inventions in his workshop at his home at Sunbury-on-Thames, assisted by a number of scientific workers. He had been educated by governesses, but he lacked a sound scientific background. His inventions, rarely systematically pursued, ranged from electrolytic processes for making copper sheets and parabolic reflectors to a process for inlaying and decorating metallic surfaces. Overall, however, he is best known for the invention of "sherardizing", the process for producing a rustproof coating of zinc on small metallic articles. The discovery came by chance, when he was annealing iron and steel packed in zinc dust to exclude air. The metal was found to be coated with a thin layer of zinc with some surface penetration. The first patent for the process was obtained in 1900, and later the American rights were sold, with a company being formed in 1908 to control them. A small plant was set up in Chelsea, London, to develop the process to the point where it could be carried out on a commercial scale in a plant in Willesden. Sherardizing has not been a general protective finish, but is restricted to articles such as nuts and bolts which are then painted or finished. The process was still in use in 1977, operated by the Zinc Alloy Company (London) Ltd.

[br]

Further Reading

C.A.Smith, 1978, "Sherard Cowper-Coles: a review of the inception of sherardizing", Transactions of the Newcomen Society 49:1–4.

LRD

De Forest, Lee

SUBJECT AREA: Broadcasting, Electronics and information technology, Photography, film and optics, Recording, Telecommunications

[br]

b. 26 August 1873 Council Bluffs, Iowa, USA

d. 30 June 1961 Hollywood, California, USA

[br]

American electrical engineer and inventor principally known for his invention of the Audion, or triode, vacuum tube; also a pioneer of sound in the cinema.

[br]

De Forest was born into the family of a Congregational minister that moved to Alabama in 1879 when the father became President of a college for African-Americans; this was a position that led to the family's social ostracism by the white community. By the time he was 13 years old, De Forest was already a keen mechanical inventor, and in 1893, rejecting his father's plan for him to become a clergyman, he entered the Sheffield Scientific School of Yale University. Following his first degree, he went on to study the propagation of electromagnetic waves, gaining a PhD in physics in 1899 for his thesis on the "Reflection of Hertzian Waves from the Ends of Parallel Wires", probably the first US thesis in the field of radio.

He then joined the Western Electric Company in Chicago where he helped develop the infant technology of wireless, working his way up from a modest post in the production area to a position in the experimental laboratory. There, working alone after normal working hours, he developed a detector of electromagnetic waves based on an electrolytic device similar to that already invented by Fleming in England. Recognizing his talents, a number of financial backers enabled him to set up his own business in 1902 under the name of De Forest Wireless Telegraphy Company; he was soon demonstrating wireless telegraphy to interested parties and entering into competition with the American Marconi Company.

Despite the failure of this company because of fraud by his partners, he continued his experiments; in 1907, by adding a third electrode, a wire mesh, between the anode and cathode of the thermionic diode invented by Fleming in 1904, he was able to produce the amplifying device now known as the triode valve and achieve a sensitivity of radio-signal reception much greater than possible with the passive carborundum and electrolytic detectors hitherto available. Patented under the name Audion, this new vacuum device was soon successfully used for experimental broadcasts of music and speech in New York and Paris. The invention of the Audion has been described as the beginning of the electronic era. Although much development work was required before its full potential was realized, the Audion opened the way to progress in all areas of sound transmission, recording and reproduction. The patent was challenged by Fleming and it was not until 1943 that De Forest's claim was finally recognized.

Overcoming the near failure of his new company, the De Forest Radio Telephone Company, as well as unsuccessful charges of fraudulent promotion of the Audion, he continued to exploit the potential of his invention. By 1912 he had used transformer-coupling of several Audion stages to achieve high gain at radio frequencies, making long-distance communication a practical proposition, and had applied positive feedback from the Audion output anode to its input grid to realize a stable transmitter oscillator and modulator. These successes led to prolonged patent litigation with Edwin Armstrong and others, and he eventually sold the manufacturing rights, in retrospect often for a pittance.

During the early 1920s De Forest began a fruitful association with T.W.Case, who for around ten years had been working to perfect a moving-picture sound system. De Forest claimed to have had an interest in sound films as early as 1900, and Case now began to supply him with photoelectric cells and primitive sound cameras. He eventually devised a variable-density sound-on-film system utilizing a glow-discharge modulator, the Photion. By 1926 De Forest's Phonofilm had been successfully demonstrated in over fifty theatres and this system became the basis of Movietone. Though his ideas were on the right lines, the technology was insufficiently developed and it was left to others to produce a system acceptable to the film industry. However, De Forest had played a key role in transforming the nature of the film industry; within a space of five years the production of silent films had all but ceased.

In the following decade De Forest applied the Audion to the development of medical diathermy. Finally, after spending most of his working life as an independent inventor and entrepreneur, he worked for a time during the Second World War at the Bell Telephone Laboratories on military applications of electronics.

[br]

Principal Honours and Distinctions

Institute of Electronic and Radio Engineers Medal of Honour 1922. President, Institute of Electronic and Radio Engineers 1930. Institute of Electrical and Electronics Engineers Edison Medal 1946.

Bibliography

1904, "Electrolytic detectors", Electrician 54:94 (describes the electrolytic detector). 1907, US patent no. 841,387 (the Audion).

1950, Father of Radio, Chicago: WIlcox \& Follett (autobiography).

De Forest gave his own account of the development of his sound-on-film system in a series of articles: 1923. "The Phonofilm", Transactions of the Society of Motion Picture Engineers 16 (May): 61–75; 1924. "Phonofilm progress", Transactions of the Society of Motion Picture Engineers 20:17–19; 1927, "Recent developments in the Phonofilm", Transactions of the Society of Motion Picture Engineers 27:64–76; 1941, "Pioneering in talking pictures", Journal of the Society of Motion Picture Engineers 36 (January): 41–9.

Further Reading

G.Carneal, 1930, A Conqueror of Space (biography).

I.Levine, 1964, Electronics Pioneer, Lee De Forest (biography).

E.I.Sponable, 1947, "Historical development of sound films", Journal of the Society of Motion Picture Engineers 48 (April): 275–303 (an authoritative account of De Forest's sound-film work, by Case's assistant).

W.R.McLaurin, 1949, Invention and Innovation in the Radio Industry.

C.F.Booth, 1955, "Fleming and De Forest. An appreciation", in Thermionic Valves 1904– 1954, IEE.

V.J.Phillips, 1980, Early Radio Detectors, London: Peter Peregrinus.

KF / JW

Deville, Henri Etienne Sainte-Claire

SUBJECT AREA: Metallurgy

[br]

b. 11 March 1818 St Thomas, Virgin Islands

d. 1 July 1881 Boulogne-sur-Seine, France

[br]

French chemist and metallurgist, pioneer in the large-scale production of aluminium and other light metals.

[br]

Deville was the son of a prosperous shipowner with diplomatic duties in the Virgin Islands. With his elder brother Charles, who later became a distinguished physicist, he was sent to Paris to be educated. He took his degree in medicine in 1843, but before that he had shown an interest in chemistry, due particularly to the lectures of Thenard. Two years later, with Thenard's influence, he was appointed Professor of Chemistry at Besançon. In 1851 he was able to return to Paris as Professor at the Ecole Normale Supérieure. He remained there for the rest of his working life, greatly improving the standard of teaching, and his laboratory became one of the great research centres of Europe. His first chemical work had been in organic chemistry, but he then turned to inorganic chemistry, specifically to improve methods of producing the new and little-known metal aluminium. Essentially, the process consisted of forming sodium aluminium trichloride and reducing it with sodium to metallic aluminium. He obtained sodium in sufficient quantity by reducing sodium carbonate with carbon. In 1855 he exhibited specimens of the metal at the Paris Exhibition, and the same year Napoleon III asked to see them, with a view to using it for breastplates for the Army and for spoons and forks for State banquets. With the resulting government support, he set up a pilot plant at Jarvel to develop the process, and then set up a small company, the Société d'Aluminium at Nan terre. This raised the output of this attractive and useful metal, so it could be used more widely than for the jewellery to which it had hitherto been restricted. Large-scale applications, however, had to await the electrolytic process that began to supersede Deville's in the 1890s. Deville extended his sodium reduction method to produce silicon, boron and the light metals magnesium and titanium. His investigations into the metallurgy of platinum revolutionized the industry and led in 1872 to his being asked to make the platinum-iridium (90–10) alloy for the standard kilogram and metre. Deville later carried out important work in high-temperature chemistry. He grieved much at the death of his brother Charles in 1876, and his retirement was forced by declining health in 1880; he did not survive for long.

[br]

Bibliography

Deville published influential books on aluminium and platinum; these and all his publications are listed in the bibliography in the standard biography by J.Gray, 1889, Henri Sainte-Claire Deville: sa vie et ses travaux, Paris.

Further Reading

M.Daumas, 1949, "Henri Sainte-Claire Deville et les débuts de l'industrie de l'aluminium", Rev.Hist.Sci 2:352–7.

J.C.Chaston, 1981, "Henri Sainte-Claire Deville: his outstanding contributions to the chemistry of the platinum metals", Platinum Metals Review 25:121–8.

LRD

Elder, John

SUBJECT AREA: Ports and shipping, Steam and internal combustion engines

[br]

b. 9 March 1824 Glasgow, Scotland

d. 17 September 1869 London, England

[br]

Scottish engineer who introduced the compound steam engine to ships and established an important shipbuilding company in Glasgow.

[br]

John was the third son of David Elder. The father came from a family of millwrights and moved to Glasgow where he worked for the well-known shipbuilding firm of Napier's and was involved with improving marine engines. John was educated at Glasgow High School and then for a while at the Department of Civil Engineering at Glasgow University, where he showed great aptitude for mathematics and drawing. He spent five years as an apprentice under Robert Napier followed by two short periods of activity as a pattern-maker first and then a draughtsman in England. He returned to Scotland in 1849 to become Chief Draughtsman to Napier, but in 1852 he left to become a partner with the Glasgow general engineering company of Randolph Elliott \& Co. Shortly after his induction (at the age of 28), the engineering firm was renamed Randolph Elder \& Co.; in 1868, when the partnership expired, it became known as John Elder \& Co. From the outset Elder, with his partner, Charles Randolph, approached mechanical (especially heat) engineering in a rigorous manner. Their knowledge and understanding of entropy ensured that engine design was not a hit-and-miss affair, but one governed by recognition of the importance of the new kinetic theory of heat and with it a proper understanding of thermodynamic principles, and by systematic development. In this Elder was joined by W.J.M. Rankine, Professor of Civil Engineering and Mechanics at Glasgow University, who helped him develop the compound marine engine. Elder and Randolph built up a series of patents, which guaranteed their company's commercial success and enabled them for a while to be the sole suppliers of compound steam reciprocating machinery. Their first such engine at sea was fitted in 1854 on the SS Brandon for the Limerick Steamship Company; the ship showed an improved performance by using a third less coal, which he was able to reduce still further on later designs.

Elder developed steam jacketing and recognized that, with higher pressures, triple-expansion types would be even more economical. In 1862 he patented a design of quadruple-expansion engine with reheat between cylinders and advocated the importance of balancing reciprocating parts. The effect of his improvements was to greatly reduce fuel consumption so that long sea voyages became an economic reality.

His yard soon reached dimensions then unequalled on the Clyde where he employed over 4,000 workers; Elder also was always interested in the social welfare of his labour force. In 1860 the engine shops were moved to the Govan Old Shipyard, and again in 1864 to the Fairfield Shipyard, about 1 mile (1.6 km) west on the south bank of the Clyde. At Fairfield, shipbuilding was commenced, and with the patents for compounding secure, much business was placed for many years by shipowners serving long-distance trades such as South America; the Pacific Steam Navigation Company took up his ideas for their ships. In later years the yard became known as the Fairfield Shipbuilding and Engineering Company Ltd, but it remains today as one of Britain's most efficient shipyards and is known now as Kvaerner Govan Ltd.

In 1869, at the age of only 45, John Elder was unanimously elected President of the Institution of Engineers and Shipbuilders in Scotland; however, before taking office and giving his eagerly awaited presidential address, he died in London from liver disease. A large multitude attended his funeral and all the engineering shops were silent as his body, which had been brought back from London to Glasgow, was carried to its resting place. In 1857 Elder had married Isabella Ure, and on his death he left her a considerable fortune, which she used generously for Govan, for Glasgow and especially the University. In 1883 she endowed the world's first Chair of Naval Architecture at the University of Glasgow, an act which was reciprocated in 1901 when the University awarded her an LLD on the occasion of its 450th anniversary.

[br]

Principal Honours and Distinctions

President, Institution of Engineers and Shipbuilders in Scotland 1869.

Further Reading

Obituary, 1869, Engineer 28.

1889, The Dictionary of National Biography, London: Smith Elder \& Co. W.J.Macquorn Rankine, 1871, "Sketch of the life of John Elder" Transactions of the

Institution of Engineers and Shipbuilders in Scotland.

Maclehose, 1886, Memoirs and Portraits of a Hundred Glasgow Men.

The Fairfield Shipbuilding and Engineering Works, 1909, London: Offices of Engineering.

P.M.Walker, 1984, Song of the Clyde, A History of Clyde Shipbuilding, Cambridge: PSL.

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge: Cambridge University Press (covers Elder's contribution to the development of steam engines).

RLH / FMW

Field, Cyrus West

SUBJECT AREA: Telecommunications

[br]

b. 30 November 1819 Stockbridge, Massachusetts, USA

d. 12 July 1892 New York City, New York, USA

[br]

American financier and entrepreneur noted for his successful promotion of the first transatlantic telegraph cable.

[br]

At the age of 15 Field left home to seek his fortune in New York, starting work on Broadway as an errand boy for $1 per week. Returning to Massachusetts, in 1838 he became an assistant to his brother Matthew, a paper-maker, leaving to set up his own business two years later. By the age of 21 he was also a partner in a New York firm of paper wholesalers, but this firm collapsed because of large debts. Out of the wreckage he set up Cyrus W.Field \& Co., and by 1852 he had paid off all the debts. With $250,000 in the bank he therefore retired and travelled in South America. Returning to the USA, he then became involved with the construction of a telegraph line in Newfoundland by an English engineer, F.N. Osborne. Although the company collapsed, he had been fired by the dream of a transatlantic cable and in 1854 was one of the founders of the New York, Newfoundland and London Telegraph Company. He began to promote surveys and hold discussions with British telegraph pioneers and with Isambard Brunel, who was then building the Great Eastern steamship. In 1856 he helped to set up the Atlantic Telegraph Company in Britain and, as a result of his efforts and those of the British physicist and inventor Sir William Thomson (Lord Kelvin), work began in 1857 on the laying of the first transatlantic cable from Newfoundland to Ireland. After many tribulations the cable was completed on 5 August 1857, but it failed after barely a month. Following several unsuccessful attempts to repair and replace it, the cable was finally completed on 27 July 1866. Building upon his success, Field expanded his business interests. In 1877 he bought a controlling interest in and was President of the New York Elevated Railroad Company. He also helped develop the Wabash Railroad and became owner of the New York Mail and Express newspaper; however, he subsequently suffered large financial losses.

[br]

Principal Honours and Distinctions

Congressional Gold Medal.

Further Reading

A.C.Clarke, 1958, Voice Across the Sea, London: Frederick Muller (describes the development of the transatlantic telegraph).

H.M.Field, 1893, Story of the Atlantic Telegraph (also describes the transatlantic telegraph development).

L.J.Judson (ed.), 1893, Cyrus W.Field: His Life and Work (a complete biography).

KF

Gilbert, John

SUBJECT AREA: Canals, Mining and extraction technology

[br]

b. 1724 Cotton Hall, Cotton, Staffordshire, England

d. 3 August 1795 Worsley, Lancashire, England

[br]

English land agent, mining engineer and canal entrepreneur.

[br]

Younger son of a gentleman farmer, Gilbert was apprenticed to Matthew Boulton, a buckle maker of Birmingham and father of the Matthew Boulton who was associated with James Watt. He also gained mining experience. Through the influence of his older brother, Thomas Gilbert, he became Land Agent to the Duke of Bridgewater (Francis Egerton) for the Worsley estate. He proposed extensions to the underground waterway system and also made a preliminary survey for a canal from Worsley to Salford, a project which Brindley joined as Assistant Engineer. Gilbert was therefore the prime mover in the construction of the Bridgewater Canal, which received its Act in 1759. He then collected evidence for the second Act to permit construction of the aqueduct across the Irwell at Barton. He was involved in a consortium with his brother Thomas and Earl Gower to develop the Earl's East Shropshire mines and to build the Shrewsbury and the Shropshire Coal Canals. He also excavated the Speedwell Mine at Castleton in Derbyshire between 1774 and 1781 and constructed the underground canal to serve the workings. With his brother, he was involved in the promotion of the Trent \& Mersey Canal and was a shareholder in the undertaking. Among his other entrepreneurial activities, he entered the canal-carrying business. His last work was beginning the underground inclined planes at Worsley, but these were not completed until after his death. His important place in the historical development of the inland navigational system in England has been very much overlooked.

[br]

Further Reading

P.Lead, 1990, Agents of Revolution: John and Thomas Gilbert-Entrepreneurs, Keele University Centre for Local History.

JHB

Jansky, Karl Guthe

SUBJECT AREA: Electronics and information technology, Telecommunications

[br]

b. 22 October 1905 Norman, Oklahoma, USA

d. 14 February 1950 Red Bank, New Jersey, USA

[br]

American radio engineer who discovered stellar radio emission.

[br]

Following graduation from the University of Wisconsin in 1928 and a year of postgraduate study, Jansky joined Bell Telephone Laboratories in New Jersey with the task of establishing the source of interference to telephone communications by radio. To this end he constructed a linear-directional short-wave antenna and eventually, in 1931, he concluded that the interference actually came from the stars, the major source being the constellation Sagittarius in the direction of the centre of the Milky Way. Although he continued to study the propagation of short radio waves and the nature of observed echoes, it was left to others to develop the science of radioastronomy and to use the creation of echoes for radiolocation. Although he received no scientific award for his discovery, Jansky's name is primarily honoured by its use as the unit of stellar radio-emission strength.

[br]

Bibliography

1935, "Directional studies of atmospherics at high frequencies", Proceedings of the Institute of Radio Engineers 23:1,158.

1935, "A note on the sources of stellar interference", Proceedings of the Institute of Radio

Engineers.

1937, "Minimum noise levels obtained on short-wave radio receiving systems", Proceedings of the Institute of Radio Engineers 25:1,517.

1941, "Measurements of the delay and direction of arrival of echoes from nearby short-wave transmitters", Proceedings of the Institute of Radio Engineers 29:322.

Further Reading

P.C.Mahon, 1975, BellLabs, Mission Communication. The Story of the Bell Labs.

W.I.Sullivan (ed.), 1984, The Early Years of Radio-Astronomy: Reflections 50 Years after Jansky's Discovery, Cambridge: Cambridge University Press.

See also: Appleton, Sir Edward Victor

KF

Marconi, Marchese Guglielmo

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 25 April 1874 Bologna, Italy

d. 20 July 1937 Rome, Italy

[br]

Italian radio pioneer whose inventiveness and business skills made radio communication a practical proposition.

[br]

Marconi was educated in physics at Leghorn and at Bologna University. An avid experimenter, he worked in his parents' attic and, almost certainly aware of the recent work of Hertz and others, soon improved the performance of coherers and spark-gap transmitters. He also discovered for himself the use of earthing and of elevated metal plates as aerials. In 1895 he succeeded in transmitting telegraphy over a distance of 2 km (1¼ miles), but the Italian Telegraph authority rejected his invention, so in 1896 he moved to England, where he filed the first of many patents. There he gained the support of the Chief Engineer of the Post Office, and by the following year he had achieved communication across the Bristol Channel.

The British Post Office was also slow to take up his work, so in 1897 he formed the Wireless Telegraph \& Signal Company to work independently. In 1898 he sold some equipment to the British Army for use in the Boer War and established the first permanent radio link from the Isle of Wight to the mainland. In 1899 he achieved communication across the English Channel (a distance of more than 31 miles or 50 km), the construction of a wireless station at Spezia, Italy, and the equipping of two US ships to report progress in the America's Cup yacht race, a venture that led to the formation of the American Marconi Company. In 1900 he won a contract from the British Admiralty to sell equipment and to train operators. Realizing that his business would be much more successful if he could offer his customers a complete radio-communication service (known today as a "turnkey" deal), he floated a new company, the Marconi International Marine Communications Company, while the old company became the Marconi Wireless Telegraph Company.

His greatest achievement occurred on 12 December 1901, when Morse telegraph signals from a transmitter at Poldhu in Cornwall were received at St John's, Newfoundland, a distance of some 2,100 miles (3,400 km), with the use of an aerial flown by a kite. As a result of this, Marconi's business prospered and he became internationally famous, receiving many honours for his endeavours, including the Nobel Prize for Physics in 1909. In 1904, radio was first used to provide a daily bulletin at sea, and in 1907 a transatlantic wireless telegraphy service was inaugurated. The rescue of 1,650 passengers from the shipwreck of SS Republic in 1909 was the first of many occasions when wireless was instrumental in saving lives at sea, most notable being those from the Titanic on its maiden voyage in April 1912; more lives would have been saved had there been sufficient lifeboats. Marconi was one of those who subsequently pressed for greater safety at sea. In 1910 he demonstrated the reception of long (8 km or 5 miles) waves from Ireland in Buenos Aires, but after the First World War he began to develop the use of short waves, which were more effectively reflected by the ionosphere. By 1918 the first link between England and Australia had been established, and in 1924 he was awarded a Post Office contract for short-wave communication between England and the various parts of the British Empire.

With his achievements by then recognized by the Italian Government, in 1915 he was appointed Radio-Communications Adviser to the Italian armed forces, and in 1919 he was an Italian delegate to the Paris Peace Conference. From 1921 he lived on his yacht, the Elettra, and although he joined the Fascist Party in 1923, he later had reservations about Mussolini.

[br]

Principal Honours and Distinctions

Nobel Prize for Physics (jointly with K.F. Braun) 1909. Russian Order of S t Anne. Commander of St Maurice and St Lazarus. Grand Cross of the Order of the Crown (i.e. Knight) of Italy 1902. Freedom of Rome 1903. Honorary DSc Oxford. Honorary LLD Glasgow. Chevalier of the Civil Order of Savoy 1905. Royal Society of Arts Albert Medal. Honorary knighthood (GCVO) 1914. Institute of Electrical and Electronics Engineers Medal of Honour 1920. Chairman, Royal Society of Arts 1924. Created Marquis (Marchese) 1929. Nominated to the Italian Senate 1929. President, Italian Academy 1930. Rector, University of St Andrews, Scotland, 1934.

Bibliography

1896, "Improvements in transmitting electrical impulses and in apparatus thereof", British patent no. 12,039.

1 June 1898, British patent no. 12,326 (transformer or "jigger" resonant circuit).

1901, British patent no. 7,777 (selective tuning).

1904, British patent no. 763,772 ("four circuit" tuning arrangement).

Further Reading

D.Marconi, 1962, My Father, Marconi.

W.J.Baker, 1970, A History of the Marconi Company, London: Methuen.

KF