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101 Weber, Wilhelm Eduard
SUBJECT AREA: Electricity[br]b. 24 October 1804 Wittenberg, Germanyd. 23 June 1891 Göttingen, Germany[br]German physicist, the founder of precise measurement of electrical quantities.[br]Weber began scientific experiments at an early age and entered the University of Halle, where he came under the influence of J.S.C.Schweigger, inventor of the galvanometer. Completing his education with a dissertation on the theory of organ pipes and making important contributions to the science of acoustics, he was awarded a lectureship and later an assistant professorship at Halle. Weber was offered the Chair of Physics at Göttingen in 1831 and jointly with Gauss began investigations into the precision measurement of magnetic quantities. In 1841 he invented the electrodynamometer type of electrical measuring instrument. This was a development of the galvanometer in which, instead of a needle, a small coil was suspended within an outer coil. A current flowing through both coils tended to turn the inner coil, the sine of the angle through which the suspending wires were twisted being proportional to the square of the strength of the current. A variation of the electrodynamometer was capable of measuring directly the power in electrical circuits.The introduction by Weber of a system of absolute units for the measurement of electrical quantities was a most important step in electrical science. He had a considerable influence on the British Association committees on electrical standards organized in 1861 to promote a coherent system of electrical units. Weber's ideas also led him to define elementary electric particles, ascribing mass and charge to them. His name was used for a time before 1883 as the unit of electric current, until the name "ampere" was proposed by Helmholtz. Since 1948 the term "weber" has been used for the SI unit of magnetic flux.[br]Principal Honours and DistinctionsFRS 1850. Royal Society Copley Medal 1859.Bibliography1892–4, William Weber's Werke, 6 vols, Berlin.Further ReadingP.Lenard, 1954, Great Men of Science, London, pp. 263–70 (a reliable, short biography). C.C.Gillispie (ed.), 1976, Dictionary of Scientific Biography, Vol. XIV, New York, pp.203–9 (discusses his theoretical contributions).S.P.Bordeau, 1982, Volts to Herz, Minneapolis, pp. 172 and 181 (discusses Weber's influence on contemporary scientists).GW -
102 Europäische Agentur für Gesundheitsschutz und Sicherheit am Arbeitsplatz
Europäische Agentur für Gesundheitsschutz und Sicherheit am Arbeitsplatz
European Agency for Health and Safety at Work;
• Einheitliche Europäisch Akte (EEA) (Europäische Kommission) Single European Act (SEA);
• Europäischer Aktionsplan zur Förderung von Innovationen European action plan to promote innovation;
• Europäisches Amt für Betrugsbekämpfung European Anti-fraud Office (OLAF);
• Europäisches Amt für humanitäre Hilfe European Community Humanitarian Office (ECHO);
• Europäische Arbeitnehmerrechte European employee rights;
• Europäische Atomenergiegesellschaft (EAEG) European Atomic Energy Community (EURATOM);
• Europäischer Ausrichtungs- und Garantiefonds für die Landwirtschaft (EAGFL) European Agricultural Guidance and Guarantee Fund (EAGGF);
• Europäische Auszeichnungen für Umweltqualität European awards for environmental quality;
• Europäische Bank für Wiederaufbau und Entwicklung (EBWE) European Bank for Reconstruction and Development (EBRD);
• Europäische Bankenvereinigung European Bank Federation (EBF);
• Europäische Beschäftigungs- und Sozialpolitik European employment and social policy;
• Europäische Beschäftigungsstrategie European employment strategy;
• Europäischer Betriebsrat European works council;
• Europäische Binnentransportorganisation European Central Inland Transport Organization;
• Europäischer Börsenindex Eurosyndicate index;
• Europäischer Bürgerbeauftragter European Ombudsman;
• Europäische Einigung European integration;
• Europäischer Entwicklungsfonds (EEF) European Development Fund (EDF);
• Europäische Exekutiven European executive bodies;
• Europäischer Fonds European Fund (EF);
• Europäischer Fonds für Regionalentwicklung (regionale Entwicklung) (EFRE) European Regional Development Fund (ERDF);
• Europäische Forschungsinfrastrukturen European research infrastructures;
• Europäisches Forschungsinstitut für Raumordnung und Städteplanung European Research Institute for Regional and Urban Planning;
• Europäische Forschungsprojekte European research projects;
• Europäische Freihandelszone (EFTA) European Free Trade Association (EFTA);
• Europäischer Führerschein European driving licence (Br.) (license, US);
• Europäisches Fürsorgeabkommen European Convention on Social and Medical Assistance;
• Europäischer Gedanke Europeanism;
• Europäische Gemeinschaft European Community (EC);
• Europäische Politische Gemeinschaft (EPG) European Political Community;
• Europäische Gemeinschaft für Kohle und Stahl European Coal and Steel Community;
• aus Kreisen in der Europäisch Gemeinschaft verlautet (EU) Community sources say;
• gegen Anordnungen der Europäischen Gemeinschaft verstoßen (EU) to contravene Community regulations;
• der Europäischen Gemeinschaftsorganisation beitreten to enter into the European Communities;
• Europäische Gemeinschaftsregion Common Market territory;
• Europäisches Gericht erster Instanz European Court of First Instance;
• Europäischer Gerichtshof (EuGH)European Court of Justice (ECJ);
• Europäischer Gerichtshof für Menschenrechte European Court of Human Rights (ECHR);
• Europäischer Gesamtdurchschnitt overall European average;
• Europäische Gesellschaft für Physik European Physical Society (EPS);
• Europäischer Gewerkschaftsbund (EGB) European Trade Union Confederation (ETUC);
• Europäisches Gipfeltreffen des sozialen Dialogs European Social Dialogue Summit;
• Europäisches Gleichstellungsrecht European equal opportunities legislation;
• Europäische Gleichstellungsrechte European equal opportunities rights;
• Europäische Grenzregion Europe’s border region;
• Europäische Identität stärken to reinforce the European identity;
• Europäischer Informationsdienst für den lokalen Verkehr European local transport information service (ELTIS);
• Europäische Integration European integration;
• Europäisch wirtschaftliche Interessenvereinigung European Economic Interest Grouping (EEIG);
• Europäische Investitionsbank (EIB) European Investment Bank (EIB);
• Europäische Kernenergieagentur (EKA) European Nuclear Energy Agency (ENEA);
• Europäisches Komitee für Normung European Committee for Coordination of Standards;
• Europäischer Kommissar European Commissioner;
• Europäisch Kommission für Menschenrechte European Commission of Human Rights;
• Europäische Kommunalkonferenz European Conference of Local Authorities;
• Europäische Konferenz der Verwaltungen für Post und Telekommunikation European Conference of Postal and Telecommunications Administrations;
• Europäisches Landwirtschaftsmodell European model of agriculture;
• Europäische Marktordnung European Market Regulations;
• Europäische Menschenrechtskonvention (EMRK) European Convention on Human Rights (ECHR), European Rights Convention;
• Europäisches Niederlassungsabkommen European Convention on Establishment;
• Europäische Normung European Standards;
• Europäische Organisation von Marktforschungsinstituten European Society for Opinion and Marketing Research (ESOMAR);
• Europäische Organisation für Raumforschung European Space Research Organization (ESTEC);
• Europäische Organisation für Satellitenübertragungen European Telecommunications Satellite Organization (EUTELSAT);
• Europäische Organisation zur Sicherung der Luftfahrt European Organization for the Safety of Air Navigation;
• Europäische Organisation für Wirtschaftliche Zusammenarbeit Organization for European Economic Cooperation (OEEC);
• Europäisches Parlament (EP) European Parliament (EP);
• Europäisches Patentamt European Patent Office;
• Europäische Patentorganisation European Patent Organization;
• Europäische Polizeibehörde European police force;
• Europäische Produktivitätszentrale European Productivity Agency (EPA);
• Europäischer Rat European Council;
• Europäische Raumordnungsministerkonferenz European Conference of Regional Planning Ministers;
• Europäische Rechnungseinheit European Unit of Account;
• Europäische Rechnungs- und Währungseinheit European accounting and currency unit;
• Europäischer Rechnungshof European Court of Auditors;
• Europäisches Referenzlabor für Luftverschmutzung European Reference Laboratory on Atmospheric Pullution (ERLAP);
• Europäisches Rundfunkabkommen European Broadcasting Agreement;
• Europäischer Sozialfonds (ESF) European Social Fund (ESF);
• Europäisches Sozialmodell European social model;
• Europäische Sozialvorschriften European social provisions;
• Europäischer Stabilitätspakt Pact on Stability in Europe;
• Europäischer Stellenvermittlungsservice European job placement agency;
• Europäisches Übereinkommen über die obligatorische Haftpflichtversicherung für Kraftfahrzeuge European Convention on compulsory insurance against civil liability in respect of motor vehicles;
• Europäische Übereinkunft über die internationale Patentklassifikation European Convention on the International Classification of Patents for Invention;
• Europäische Umweltagentur European Environment Agency;
• Europäisches Umweltzeichen European eco-label;
• Europäische Union (EU) European Union (EU);
• Europäische Verbraucherberatung (Wien) European Consumer Centre;
• Europäische Vereinigung der Finanzmaklergesellschaften European Federation of Financial Analysts Societies (EFFAS);
• Europäische Verkehrsministerkonferenz European Conference of Ministers of Transport;
• Europäische Verteidigungsgemeinschaft (EVG) European Defence Community (EDC);
• Europäisches Währungsabkommen European Monetary Agreement (EMA);
• Europäische Währungseinheit European currency unit (ECU);
• Europäisches Währungsinstitut (EWI) European Monetary Institute (EMI);
• Europäisches Währungssystem (EWS) European Monetary System (EMS);
• Europäische Währungsunion (EWU) European Monetary Union (EMU);
• Europäischer Währungsverbund European currency float;
• Europäisches Wiederaufbauprogramm European Recovery Program(me) (ERP);
• Europäische Wirtschaftsgemeinschaft European Economic Community (EEC), Euromarket, European Common Market (Br.);
• der Europäischen Wirtschaftsgemeinschaft beitreten to join the Common Market;
• Europäischer Wirtschaftsraum (EWR) European Economic Area (EEA);
• Europäische Wirtschafts- und Währungsunion European Economic and Monetary Union;
• Europäische Woche für Wissenschaft und Technologie European Science and Technology Week;
• Europäische Zahlungsunion European Payments Union (EPU);
• Europäisches Zentralbankensystem (EZBS) European System of Central Banks (ESCB);
• Europäischr Zentralverband der öffentlichen Wirtschaft European Centre for Public Enterprise (CEEP);
• Europäisches Zentrum für technische und wissenschaftliche Analysen (CSTE) European Technical and Scientific Centre (ETSC);
• Europäische Zollunion European Customs Union;
• Europäisches Zukunftsbild entwerfen to envisage a Europe of the future;
• Europäische Politische Zusammenarbeit (EPZ) European Political Cooperation (EPC);
• Europäische Zusammenarbeit zur Erweiterung des Wissens European cooperation in the pursuit of knowledge.Business german-english dictionary > Europäische Agentur für Gesundheitsschutz und Sicherheit am Arbeitsplatz
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103 cientifismo
* * *= scientism.Ex. Scientism is the belief that invariably the science of natural phenomena can be applied objectively to human society, so as to reveal the conditions for human happiness and the achievement of the general good = Cientifismo es la creencia de que normalmente la ciencia de los fenómenos naturales se puede aplicar objetivamente a la sociedad humana con objeto de revelar las condiciones de la felicidad del ser humano y alcanzar el bien general.* * *= scientism.Ex: Scientism is the belief that invariably the science of natural phenomena can be applied objectively to human society, so as to reveal the conditions for human happiness and the achievement of the general good = Cientifismo es la creencia de que normalmente la ciencia de los fenómenos naturales se puede aplicar objetivamente a la sociedad humana con objeto de revelar las condiciones de la felicidad del ser humano y alcanzar el bien general.
* * *cientifismo, cientificismoscientism* * *cientifismo = cientificismo -
104 institut
institut [ɛ̃stity]masculine noun* * *ɛ̃stitynom masculin institutePhrasal Verbs:* * *ɛ̃stity nm* * *institut nm institute.institut de beauté beauty salon ou parlourGB; institut de crédit Fin lending organization; institut d'émission Fin central bank; Institut de France body representing the five French academies; institut médico-légal forensic science laboratory; institut médico-pédagogique special school; institut de sondage polling organization.[ɛ̃stity] nom masculin[établissement] instituteinstitut de recherches/scientifique research/scientific instituteinstitut de beauté beauty salon ou parlourl'Institut du Monde ArabeArab cultural centre and library in Paris holding regular exhibitions of Arab artInstitut (de France) nom propre masculinl'Institut de France the Institut de France ≃ the Royal Society (UK), ≃ the National Science Foundation (US)L'Institut, as it is commonly known, is a learned society which includes the five Académies (the Académie française being one of them). Its headquarters are in the building of the same name on the banks of the Seine in Paris. -
105 право
1 (в субъективном смысле)сущ.right;title;(власть, полномочие) authority;power- право авторства
- право аренды
- право бенефициария
- право вето
- право владеть имуществом
- право возмездия
- право воспроизведения
- право воюющей стороны
- право выбора
- право выкупа
- право выхода
- право выхода
- право голоса
- право давности
- право денонсации
- право законодательной инициативы
- право изобретателя
- право интеллектуальной собственности
- право личной собственности
- право личности
- право на взыскание
- право на возврат
- право на вознаграждение
- право на гражданство
- право на жизнь
- право на жилище
- право на защиту
- право на избрание
- право на иск
- право на компенсацию
- право на недвижимость
- право на образование
- право на обыск
- право на переизбрание
- право на привилегию
- право на самоопределение
- право на самоуправление
- право на свободу
- право на существование
- право на труд
- право надзора
- право нанять адвоката
- право наслаждаться искусством
- право наследования
- право обжалования
- право отвода кандидата
- право отзыва
- право очной ставки
- право передоверия
- право пересмотра
- право подписи
- право пользования
- право помилования
- право потребовать адвоката
- право представлять свидетелей
- право представлять улики
- право преждепользования
- право преимущественного удовлетворения
- право преимущественной покупки
- право преследования
- право приоритета
- право продажи
- право просить помилования
- право протеста
- право самосохранения
- право свободного доступа
- право собраний
- право собственности
- право требования
- право убежища
- право удержания
- право усмотрения
- право членства
- право юридического лица
- право юрисдикции
- авторское право
- арендное право
- беспредельное право
- возвратное право
- естественное право
- законное право
- залоговое право
- избирательное право
- изобретательское право
- иметь право
- иметь законное право
- иметь полное право
- имеющий юридическое право
- использовать своё право
- конкретное право
- конституционное право
- личное право
- наследственное право
- неделимое имущественное право
- неотъемлемое право
- обусловленное право
- ограниченное право
- ограничивать право
- определять право
- оспаривать право
- осуществлять право
- патентное право
- пожизненное право
- посессорное право
- производное право
- процессуальное право
- регрессивное право
- спорное право
- субъективное право
- субъективное право
- суверенное право
- существенное право
- ущемлённое право
- юридически действительное правоправо (свободно) выбирать и развивать свою политическую, социальную, --
право ареста (удержания) имущества — (general, possessory) lien; right of retention
право владения, пользования и распоряжения — right of possession, enjoyment and disposal
право вступать в отношения с другими государствами — right to enter into relations with other states
право вступления во владение — ( недвижимостью) right of entry
право защиты своих граждан — right of protection of one’s citizens (nationals)
право исповедовать любую религию или не исповедовать никакой — right to profess or not to profess any religion
право на заключение коллективных договоров — collective bargaining right; right to bargain collectively
право на защиту моральных и материальных интересов — right to protection of moral and material interests
право на личную безопасность (неприкосновенность) — right to inviolability of the person (to personal security)
право на материальное обеспечение в старости (в случае потери трудоспособности) — right to maintenance in old age (in case of disability)
право на обеспечение на случай безработицы, болезни или инвалидности — right to security in the event of unemployment, sickness or disability
право на обжалование судебных решений — right of appeal; right to appeal against court decisions
право на пересмотр приговора — ( более высоким судом) right to have the sentence reviewed (by a higher court | tribunal)
право на свободу мирных собраний и ассоциаций — right to freedom of peaceful assembly and association
право на свободу мысли, совести и религии — right to freedom of thought, conscience and religion
право на справедливое и удовлетворительное вознаграждение — right to a just and favourable remuneration
право на суверенитет над своими ресурсами — right to sovereignty over one’s natural resources
право на судебную защиту — benefit of a counsel; right to defence; right to legal assistance (protection by the court)
право на судебную проверку законности и обоснованности содержания под стражей — right to court verification of the legality and validity of holding (smb) in custody
право не отвечать на вопросы — right to keep (remain) silent; right to silence
право обжаловать действия должностных лиц — right to lodge a complaint against the actions of officials
право оборота (регресса) — right of a recourse (relief, regress)
право принадлежать или не принадлежать к международным организациям — right to belong or not to belong to international organizations
право регресса (оборота) — right of a recourse (relief, regress)
право считаться невиновным до тех пор, пока вина не будет доказана в установленном законом порядке — right to be presumed innocent until proved guilty according to law
право удержания, предусмотренное законом — statutory lien
право участвовать в научном прогрессе и пользоваться его благами — right to share in scientific advancement (progress) and its benefits
право участия в голосовании — right to vote; suffrage; voting right
право участия в управлении государственными делами — right to take part in the conduct of public affairs
право, связанное с недвижимостью — tenement
право ( государства) на принудительное отчуждение частной собственности — eminent domain
право ( государства) распоряжаться своими богатствами и естественными ресурсами — right (of a state) to dispose of its wealth and its natural resources
право ( компетенция) суда — court’s power
право ( продавца) удерживать товар ( до уплаты покупной цены) — vendor’s lien
абсолютное (неограниченное) право — absolute right; right in rem
без \правоа оборота (регресса) — without the right of recourse (relief, regress)
без \правоа — ( при покупке акций) ex right(s)
безусловное право собственности — estate (interest) in fee-simple; fee; fee-simple; ( на недвижимость - фригольд) freehold
большие \правоа — extensive rights
быть наделённым \правом — to be vested with a right (with authority)
в силу \правоа — by right of
верховенство \правоа — rule of law; supremacy of law
вещное (имущественное) право — interest in estate (in property); proprietary interest (right); real right; right in rem
взаимные \правоа и обязанности — reciprocal rights and obligations
включая \правоа — ( при покупке акций) cum rights
воспользоваться \правом — to avail oneself of a right
восстанавливать кого-л в \правоах — to rehabilitate; restore smb in his | her rights
восстанавливать свои \правоа — to restore one’s rights
восстановление в \правоах — rehabilitation; restoration of rights
входить в \правоа наследования — to come into a legacy
гражданские \правоа — civic (civil) rights
давать (предоставлять) кому-л право — to authorize (empower, enable) smb (to + inf); entitle smb (to); give (grant) smb a right
затрагивать чьи-л \правоа — to affect (impair, prejudice) smb’s rights
защищать (отстаивать) свои \правоа — to assert oneself; assert (defend, maintain) one’s rights
заявлять (предъявлять) право — (на) to claim (for); claim a right; lay (lodge, raise) a claim (to)
злоупотребление \правом — abuse (misuse) of a right
злоупотреблять \правом — to abuse (misuse) a right
имущественное (вещное) право — interest in estate (in property); proprietary interest (right); real right; right in rem
исключительное (монопольное) право — exclusive (sole) right; prerogative
лишать кого-л \правоа — to debar smb (from); deny smb (deprive, divest smb of) a right
лишать кого-л избирательного \правоа — to deny smb (deprive, divest smb of) his | her electoral right; disfranchise smb
лишаться \правоа — to be denied (deprived of) a right; forfeit (lose) a right
лишение \правоа возражения — estoppel
лишение \правоа выкупа заложенного имущества — foreclosure
лишение \правоа — ( правопоражение) deprivation (extinction, forfeit, revocation) of a right; disability; disfranchisement; disqualification; incapacity; incapacitation
лишение гражданских прав — deprivation (forfeit, revocation) of civil rights
монопольное (исключительное) право — exclusive (sole) right; prerogative
на основе всеобщего, равного и прямого избирательного \правоа при тайном голосовании — on the basis of universal, equal and direct suffrage by secret ballot
на равных \правоах — on a par; on the basis of parity
наделять кого-л \правом собственности — to entitle smb (to); vest smb with a title (in) (to)
наделять кого-л \правом — to authorize (empower) smb (to + inf); vest a right in smb; vest smb with a right
наносить ущерб чьим-л \правоам — to affect (impair, prejudice) smb’s rights
нарушать чьи-л \правоа — to infringe (violate) smb’s rights
нарушение \правоа — infringement (violation) of a right
нарушение авторского \правоа — infringement (violation) of a copyright; piracy
не признавать \правоа — to disclaim a right
неограниченное (абсолютное) право — absolute right; right in rem
обладание \правом — eligibility
обязательственное (относительное) право — right in personam; ( из договора) contractual right
ограничение \правоа — circumscription (curtailment, limitation, restriction) of a right; ( на возражение) estoppel
основные \правоа — basic (fundamental, primary) rights
осуществлять свои \правоа принудительно (в судебном порядке) — to enforce one’s rights
отказ от \правоа — abandonment (disclaimer, renunciation, surrender, waiver) of a right; quitclaim
отказываться от \правоа — to abandon (disclaim, drop, remise, renounce, resign, surrender, waive) a right; quitclaim
отстаивать (защищать) свои \правоа — to assert oneself; assert (defend, maintain) one’s rights
передавать (переуступать) право — to assign (cede, transfer) a right
передача \правоа собственности — conveyance of ownership
передача \правоа — assignment (cession, transfer) of a right
по \правоу — (as) of right; by right
по собственному \правоу — in one’s own right
политические \правоа — political rights
получать (приобретать) право — to acquire (obtain) a right; become entitled (to)
пользоваться \правом — to enjoy (exercise) one’s right
попирать чьи-л \правоа — to trample on (upon) smb’s rights
поражение в \правоах — deprivation (extinction, forfeit, revocation) of a right; disability; disfranchisement; disqualification; incapacity; incapacitation
порок \правоа собственности — defect in the title
посягательство на чьи-л \правоа — encroachment (infringement, trespass) on (upon) smb’s rights
посягать на (ущемлять) чьи-л \правоа — to encroach (infringe, trespass, usurp) on (upon) smb’s rights
превышать свои \правоа — ( полномочия) to exceed (overstep) one’s powers
предоставлять (давать) кому-л право — to authorize (empower, enable) smb (to + inf); entitle smb (to); give (grant) smb a right
предъявлять (заявлять) право — (на) to claim (for); claim a right; lay (lodge, raise) a claim (to)
презюмируемое (подразумеваемое) право — implicit (implied) right; ( собственности) apparent ownership
преимущественное (преференциальное, приоритетное) право — preferential (priority, underlying) right
преимущественное право покупки — pre-emption (pre-emptive) right; (right of) first option
прекращение \правоа — termination of a right
препятствовать осуществлению \правоа — to preclude a right
при осуществлении своих прав и свобод — in the exercise of one’s rights and freedoms
приобретать (получать) право — to acquire (obtain) a right; become entitled (to)
приобретение \правоа собственности — acquisition of a title (to)
приобретение \правоа — acquisition of a right
приостановление \правоа — suspension of a right
равные \правоа — equal rights
с \правом оборота (регресса) — with the right of recourse (relief, regress)
с полным \правом — rightfully
социально-экономические \правоа — socio-economic rights
специальные \правоа заимствования — special drawing rights (SDR)
супружеские \правоа — conjugal (marital) rights
ущемлять (посягать на) чьи-л \правоа — to encroach (infringe, trespass, usurp) on (upon) smb’s rights
2 (в объективном смысле)экономическую и культурную систему — right to (freely) choose and develop one’s political, social, economic and cultural system
сущ.law- право войны
- право международной безопасности
- право международной торговли
- право международных инвестиций
- право народов
- право собственности
- право справедливости
- право торгового оборота
- авторское право
- агентское право
- административное право
- акционерное право
- арбитражное право
- арендное право
- банковское право
- брачное право
- валютное право
- вещное право
- внутригосударственное право
- воздушное право
- государственное право
- гражданское право
- гуманитарное право
- действующее право
- деликтное право
- дипломатическое право
- доказательственное право
- естественное право
- законодательное право
- земельное право
- изобретательское право
- каноническое право
- коллизионное право
- конституционное право
- консульское право
- космическое право
- личное право
- материальное право
- межгосударственное право
- международное право
- международное авторское право
- международное валютное право
- международное воздушное право
- международное гуманитарное право
- международное договорное право
- международное космическое право
- международное морское право
- международное обычное право
- международное публичное право
- международное частное право
- морское право
- налоговое право
- наследственное право
- национальное право
- обычное право
- обязательственное право
- парламентское право
- патентное право
- позитивное право
- посольское право
- прецедентное право
- процессуальное право
- публичное право
- публичное право
- римское право
- рыночное право
- светское право
- семейное право
- сравнительное право
- статутное право
- страховое право
- судебное право
- таможенное право
- торговое право
- трудовое право
- уголовное право
- финансовое право
- хозяйственное право
- церковное право
- частное право
- частное правоправо, действующее на территории страны — law of the land
право, регулирующее деятельность акционерных компаний — company law
право, регулирующее деятельность международных организаций — law of international organizations
бакалавр \правоа (прав) — Bachelor of Law(s) (B.L., LL.B.)
брачно-семейное право — marriage and family law; matrimonial law
в силу \правоа — at law
в соответствии с нормами (принципами) международного \правоа — in accordance (compliance, conformity) with the norms (principles) of international law; under international law
верховенство (господство) \правоа — rule-of-law; supremacy of law
вопрос \правоа — matter (point, question) of law
договорное (контрактное) право — contract (contractual, conventional) law; law of contract(s) (of treaties)
доктор \правоа (прав) — Doctor of Law(s) (D.L., LL.D.)
институты и нормы международного \правоа — international legal norms and institutions
источник \правоа — source of law
контрактное (договорное) право — contract (contractual, conventional) law; law of contract(s) (of treaties)
магистр \правоа (прав) — Master of Law(s) (M.L., LL.M.)
нарушение \правоа — breach (violation) of law
область \правоа — branch of law
общее (обычное) право — common (customary) law; tacit law
общие (основные) принципы международного \правоа — basic (general) principles of international law
презумпция \правоа — presumption in law; prima facie law
пробел в \правое — gap in law
субъект \правоа — person (subject) of law
теория \правоа — legal theory
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106 industrialization
Gen Mgtthe change from a society based on agriculture to one based on manufacturing. Industrialization is the process undergone in much of the developed world during the Industrial Revolution. Features of the process include automation, scientific development, the introduction of factories, the division of labor, the replacement of barter with a money-based economy, a more mobile workforce, and the growth of urban centers. The phase of development following industrialization is the postindustrial society. -
107 Abel, John Jacob
SUBJECT AREA: Medical technology[br]b. 19 May 1857 near Cleveland, Ohio, USAd. 26 May 1938 Baltimore, Maryland, USA[br]American pharmacologist and physiologist, proponent of the "artificial kidney" and the isolator of pure insulin.[br]Born of German immigrant farming stock, his early scientific education at the University of Michigan, where he graduated PhB in 1883, suffered from a financially dictated interregnum of three years. In 1884 he moved to Leipzig and worked under Ludwig, moving to Strasbourg where he obtained his MD in 1888. In 1891 he was able to return to the University of Michigan as Lecturer in Materia Medica and Therapeutics, and in 1893 he was offered the first Chair of Pharmacology at Johns Hopkins University, a position he occupied until 1932. He was a pioneer in emphasizing the importance of chemistry, in its widest sense, in medicine and physiology. In his view, "the investigator must associate himself with those who have laboured in fields where molecules and atoms rather than multi-cellular tissues or even unicellular organisms are the units of study".Soon after coming to Baltimore he commenced work on extracts from the adrenal medulla and in 1899 published his work on epinephrine. In later years he developed an "artificial kidney" which could be used to remove diffusible substances from the blood. In 1913 he was able to demonstrate the existence of free amino-acids in the blood and his investigations in this field foreshadowed not only the developments of blood and plasma transfusion but also the possibility of the management of renal failure.From 1917 to 1924 he moved to a study of the hormone content of pituitary extracts, but in 1924 he suddenly transferred his attention to the study of insulin. In 1925 he announced the discovery of pure crystalline hormone. This work at first failed to gain full acceptance, but as late as 1955 the full elucidation of the protein structure of insulin proved the final culmination of his studies.Abel's dedication to laboratory research and his disdain for matters of administration may explain the relative paucity of worldy honours awarded to such an outstanding figure.[br]Principal Honours and DistinctionsFRS.Bibliography1913, "On the removal of diffusible substances from the circulating blood by means of dialysis", Transactions of the Association of American Physiologists.Further Reading1939, Obituary Notices, Fellows of the Royal Society, London: Royal Society.1946, Biographical Memoir: John Jacob Abel. 1857–1938, Washington, DC: National Academy of Sciences.MG -
108 Born, Ignaz Edler von
[br]b. 26 December 1742 Karlsburg, Transylvania (now Alba lulia, Romania)d. 24 July 1791 Vienna, Austria[br]Austrian metallurgical and mining expert, inventor of the modern amalgamation process.[br]At the University of Prague he studied law, but thereafter turned to mineralogy, physics and different aspects of mining. In 1769–70 he worked with the mining administration in Schemnitz (now Banská Stiavnica, Slovakia) and Prague and later continued travelling to many parts of Europe, with special interests in the mining districts. In 1776, he was charged to enlarge and systematically to reshape the natural-history collection in Vienna. Three years later he was appointed Wirklicher Hofrat at the mining and monetary administration of the Austrian court.Born, who had been at a Jesuit college in his youth, was an active freemason in Vienna and exercised remarkable social communication. The intensity of his academic exchange was outstanding, and he was a member of more than a dozen learned societies throughout Europe. When with the construction of a new metallurgic plant at Joachimsthal (now Jáchymov, Czech Republic) the methods of extracting silver and gold from ores by the means of quicksilver demanded acute consideration, it was this form of scientific intercourse that induced him in 1786 to invite many of his colleagues from several countries to meet in Schemnitz in order to discuss his ideas. Since the beginnings of the 1780s Born had developed the amalgamation process as had first been applied in Mexico in 1557, by mixing the roasted and chlorinated ores with water, ingredients of iron and quicksilver in drums and having the quicksilver refined from the amalgam in the next step. The meeting led to the founding of the Societät der Bergbaukunde, the first internationally structured society of scientists in the world. He died as the result of severe injuries suffered in an accident while he was studying fire-setting in a Slovakian mine in 1770.[br]Bibliography1772–5, Lithophylacium Borniarum seu Index fossilium, 2 vols, Prague.1774 (ed.), Briefe an J.J.Ferber über mineralogische Gegenstände, Frankfurt and Leipzig.1775–84, Abhandlungen einer Privatgesellschaft in Böhmen, zur Aufnahme derMathematik, der vaterländischen Geschichte und der Naturgeschichte, 6 vols, Prague. 1786, Über das Anquicken der gold-und silberhaltigen Erze, Rohsteine, Schwarzkupferund Hüttenspeise, Vienna.1789–90, co-edited with F.W.H.von Trebra, Bergbaukunde, 2 vols, Leipzig.Further ReadingC.von Wurzbach, 1857, Biographisches Lexikon des Kaiserthums Österreich, Vol. II, pp. 71–4.L.Molnár and A Weiß, 1986, Ignaz Edler von Born und die Societät der Bergbaukunde 1786, Vienna: Bundesministerium für Handel, Gewerbe und Industrie (provides a very detailed description of his life, the amalgamation process and the society of 1786). G.B.Fettweis, and G.Hamann (eds), 1989, Über Ignaz von Born und die Societät derBergbaukunde, Vienna: Verlag der Österreichischen Akademie der Wissenschaft (provides a very detailed description).WK -
109 Clegg, Samuel
[br]b. 2 March 1781 Manchester, Englandd. 8 January 1861 Haverstock Hill, Hampstead, London, England[br]English inventor and gas engineer.[br]Clegg received scientific instruction from John Dalton, the founder of the atomic theory, and was apprenticed to Boulton \& Watt. While at their Soho factory in Birmingham, he assisted William Murdock with his experiments on coal gas. He left the firm in 1804 and set up as a gas engineer on his own account. He designed and installed gas plant and lighting in a number of factories, including Henry Lodge's cotton mill at Sowerby Bridge and in 1811 the Jesuit College at Stoneyhurst in Lancashire, the first non-industrial establishment to be equipped with gas lighting.Clegg moved to London in 1813 and successfully installed gas lighting at the premises of Rudolf Ackermann in the Strand. His success in the manufacture of gas had earned him the Royal Society of Arts Silver Medal in 1808 for furthering "the art of gas production", and in 1813 it brought him the appointment of Chief Engineer to the first gas company, the Chartered Gas, Light \& Coke Company. He left in 1817, but remained in demand to set up gas works and advise on the formation of gas companies. Throughout this time there flowed from Clegg a series of inventions of fundamental importance in the gas industry. While at Lodge's mill he had begun purifying gas by adding lime to the gas holder, and at Stoneyhurst this had become a separate lime purifier. In 1815, and again in 1818, Clegg patented the wet-meter which proved to be the basis for future devices for measuring gas. He invented the gas governor and, favouring the horizontal retort, developed the form which was to become standard for the next forty years. But after all this, Clegg joined a concern in Liverpool which failed, taking all his possessions with it. He made a fresh start in Lisbon, where he undertook various engineering works for the Portuguese government. He returned to England to find railway construction gathering pace, but he again backed a loser by engaging in the ill-fated atmospheric-rail way project. He was finally discouraged from taking part in further enterprises, but he received a government appointment as Surveying Officer to conduct enquiries in connection with the various Bills on gas that were presented to Parliament. Clegg also contributed to his son's massive treatise on the manufacture of coal gas.[br]Principal Honours and DistinctionsRoyal Society of Arts Silver Medal 1808.Further ReadingMinutes of Proceedings of the Institution of Civil Engineers (1862) 21:552–4.S.Everard, 1949, The History of the Gas light and Coke Company, London: Ernest Benn.LRD -
110 Crookes, Sir William
SUBJECT AREA: Electricity[br]b. 17 June 1832 London, Englandd. 4 April 1919 London, England[br]English chemist and physicist who carried out studies of electrical discharges and cathode rays in rarefied gases, leading to the development of the cathode ray tube; discoverer of the element thallium and the principle of the Crookes radiometer.[br]Crookes entered the Royal College of Chemistry at the age of 15, and from 1850 to 1854 held the appointment of Assistant at the college. In 1854 he became Superintendent of the Meteorological Department at the Radcliffe Observatory in Oxford. He moved to a post at the College of Science in Chester the following year. Soon after this he inherited a large fortune and set up his own private laboratory in London. There he studied the nature of electrical discharges in gases at low pressure and discovered the dark space (later named after him) that surrounds the negative electrode, or cathode. He also established that the rays produced in the process (subsequently shown by J.J.Thompson to be a stream of electrons) not only travelled in straight lines, but were also capable of producing heat and/or light upon impact with suitable anode materials. Using a variety of new methods to investigate these "cathode" rays, he applied them to the spectral analysis of compounds of selenium and, as a result, in 1861 he discovered the element thallium, finally establishing its atomic weight in 1873. Following his discovery of thallium, he became involved in two main lines of research: the properties of rarified gases, and the investigation of the elements of the "rare earths". It was also during these experiments that he discovered the principle of the Crookes radiometer, a device in which light is converted into rotational motion and which used to be found frequently in the shop windows of English opticians. Also among the fruits of this work were the Crookes tubes and the development of spectacle lenses with differential ranges of radiational absorption. In the 1870s he became interested in spiritualism and acquired a reputation for his studies of psychic phenomena, but at the turn of the century he returned to traditional scientific investigations. In 1892 he wrote about the possibility of wireless telegraphy. His work in the field of radioactivity led to the invention of the spinthariscope, an early type of detector of alpha particles. In 1900 he undertook investigations into uranium which led to the study of scintillation, an important tool in the study of radioactivity.While the theoretical basis of his work has not stood the test of time, his material discoveries, observations and investigations of new facts formed a basis on which others such as J.J. Thomson were to develop subatomic theory. His later involvement in the investigation of spiritualism led to much criticism, but could be justified on the basis of a belief in the duty to investigate all phenomena.[br]Principal Honours and DistinctionsKnighted 1897. Order of Merit 1910. FRS 1863. President, Royal Society 1913–15. Honorary LLD Birmingham. Honorary DSc Oxon, Cambridge, Sheffield, Durham, Ireland and Cape of Good Hope.Bibliography1874, On Attraction and Repulsion Resulting from Radiation.1874, "Researches in the phenomenon of spiritualism", Society of Metaphysics; reprinted in facsimile, 1986.For many years he was also Proprietor and Editor of Chemical News.Further ReadingE.E.Fournier D'Albe, 1923, Life of Sir William Crookes. Who Was Who II, 1916–28, London: A. \& C. Black. T.I.Williams, 1969, A Biographical Dictionary of Scientists. See also Braun, Karl Ferdinand.KF / MG -
111 Davidson, Robert
[br]b. 18 April 1804 Aberdeen, Scotlandd. 16 November 1894 Aberdeen, Scotland[br]Scottish chemist, pioneer of electric power and builder of the first electric railway locomotives.[br]Davidson, son of an Aberdeen merchant, attended Marischal College, Aberdeen, between 1819 and 1822: his studies included mathematics, mechanics and chemistry. He subsequently joined his father's grocery business, which from time to time received enquiries for yeast: to meet these, Davidson began to manufacture yeast for sale and from that start built up a successful chemical manufacturing business with the emphasis on yeast and dyes. About 1837 he started to experiment first with electric batteries and then with motors. He invented a form of electromagnetic engine in which soft iron bars arranged on the periphery of a wooden cylinder, parallel to its axis, around which the cylinder could rotate, were attracted by fixed electromagnets. These were energized in turn by current controlled by a simple commutaring device. Electric current was produced by his batteries. His activities were brought to the attention of Michael Faraday and to the scientific world in general by a letter from Professor Forbes of King's College, Aberdeen. Davidson declined to patent his inventions, believing that all should be able freely to draw advantage from them, and in order to afford an opportunity for all interested parties to inspect them an exhibition was held at 36 Union Street, Aberdeen, in October 1840 to demonstrate his "apparatus actuated by electro-magnetic power". It included: a model locomotive carriage, large enough to carry two people, that ran on a railway; a turning lathe with tools for visitors to use; and a small printing machine. In the spring of 1842 he put on a similar exhibition in Edinburgh, this time including a sawmill. Davidson sought support from railway companies for further experiments and the construction of an electromagnetic locomotive; the Edinburgh exhibition successfully attracted the attention of the proprietors of the Edinburgh 585\& Glasgow Railway (E \& GR), whose line had been opened in February 1842. Davidson built a full-size locomotive incorporating his principle, apparently at the expense of the railway company. The locomotive weighed 7 tons: each of its two axles carried a cylinder upon which were fastened three iron bars, and four electromagnets were arranged in pairs on each side of the cylinders. The motors he used were reluctance motors, the power source being zinc-iron batteries. It was named Galvani and was demonstrated on the E \& GR that autumn, when it achieved a speed of 4 mph (6.4 km/h) while hauling a load of 6 tons over a distance of 1 1/2 miles (2.4 km); it was the first electric locomotive. Nevertheless, further support from the railway company was not forthcoming, although to some railway workers the locomotive seems to have appeared promising enough: they destroyed it in Luddite reaction. Davidson staged a further exhibition in London in 1843 without result and then, the cost of battery chemicals being high, ceased further experiments of this type. He survived long enough to see the electric railway become truly practicable in the 1880s.[br]Bibliography1840, letter, Mechanics Magazine, 33:53–5 (comparing his machine with that of William Hannis Taylor (2 November 1839, British patent no. 8,255)).Further Reading1891, Electrical World, 17:454.J.H.R.Body, 1935, "A note on electro-magnetic engines", Transactions of the Newcomen Society 14:104 (describes Davidson's locomotive).F.J.G.Haut, 1956, "The early history of the electric locomotive", Transactions of the Newcomen Society 27 (describes Davidson's locomotive).A.F.Anderson, 1974, "Unusual electric machines", Electronics \& Power 14 (November) (biographical information).—1975, "Robert Davidson. Father of the electric locomotive", Proceedings of the Meeting on the History of Electrical Engineering Institution of Electrical Engineers, 8/1–8/17 (the most comprehensive account of Davidson's work).A.C.Davidson, 1976, "Ingenious Aberdonian", Scots Magazine (January) (details of his life).PJGR / GW -
112 Froude, William
SUBJECT AREA: Ports and shipping[br]b. 1810 Dartington, Devon, Englandd. 4 May 1879 Simonstown, South Africa[br]English naval architect; pioneer of experimental ship-model research.[br]Froude was educated at a preparatory school at Buckfastleigh, and then at Westminster School, London, before entering Oriel College, Oxford, to read mathematics and classics. Between 1836 and 1838 he served as a pupil civil engineer, and then he joined the staff of Isambard Kingdom Brunel on various railway engineering projects in southern England, including the South Devon Atmospheric Railway. He retired from professional work in 1846 and lived with his invalid father at Dartington Parsonage. The next twenty years, while apparently unproductive, were important to Froude as he concentrated his mind on difficult mathematical and scientific problems. Froude married in 1839 and had five children, one of whom, Robert Edmund Froude (1846–1924), was to succeed him in later years in his research work for the Admiralty. Following the death of his father, Froude moved to Paignton, and there commenced his studies on the resistance of solid bodies moving through fluids. Initially these were with hulls towed through a house roof storage tank by wires taken over a pulley and attached to falling weights, but the work became more sophisticated and was conducted on ponds and the open water of a creek near Dartmouth. Froude published work on the rolling of ships in the second volume of the Transactions of the then new Institution of Naval Architects and through this became acquainted with Sir Edward Reed. This led in 1870 to the Admiralty's offer of £2,000 towards the cost of an experimental tank for ship models at Torquay. The tank was completed in 1872 and tests were carried out on the model of HMS Greyhound following full-scale towing trials which had commenced on the actual ship the previous year. From this Froude enunciated his Law of Comparisons, which defines the rules concerning the relationship of the power required to move geometrically similar floating bodies across fluids. It enabled naval architects to predict, from a study of a much less expensive and smaller model, the resistance to motion and the power required to move a full-size ship. The work in the tank led Froude to design a model-cutting machine, dynamometers and machinery for the accurate ruling of graph paper. Froude's work, and later that of his son, was prodigious and covered many fields of ship design, including powering, propulsion, rolling, steering and stability. In only six years he had stamped his academic authority on the new science of hydrodynamics, served on many national committees and corresponded with fellow researchers throughout the world. His health suffered and he sailed for South Africa to recuperate, but he contracted dysentery and died at Simonstown. He will be remembered for all time as one of the greatest "fathers" of naval architecture.[br]Principal Honours and DistinctionsFRS. Honorary LLD Glasgow University.Bibliography1955, The Papers of William Froude, London: Institution of Naval Architects (the Institution also published a memoir by Sir Westcott Abell and an evaluation of his work by Dr R.W.L. Gawn of the Royal Corps of Naval Constructors; this volume reprints all Froude's papers from the Institution of Naval Architects and other sources as diverse as the British Association, the Royal Society of Edinburgh and the Institution of Civil Engineers.Further ReadingA.T.Crichton, 1990, "William and Robert Edmund Froude and the evolution of the ship model experimental tank", Transactions of the Newcomen Society 61:33–49.FMW -
113 Garforth, William Edward
SUBJECT AREA: Mining and extraction technology[br]b. 1845 Dukinfield, Cheshire, Englandd. 1 October 1921 Pontefract, Yorkshire, England[br]English colliery manager, pioneer in machine-holing and the safety of mines.[br]After Menzies conceived his idea of breaking off coal with machines in 1761, many inventors subsequently followed his proposals through into the practice of underground working. More than one century later, Garforth became one of the principal pioneers of machine-holing combined with the longwall method of working in order to reduce production costs and increase the yield of coal. Having been appointed agent to Pope \& Pearson's Collieries, West Yorkshire, in 1879, of which company he later became Managing Director and Chairman, he gathered a great deal of experience with different methods of cutting coal. The first disc machine was exhibited in London as early as 1851, and ten years later a pick machine was invented. In 1893 he introduced an improved type of deep undercutting machine, his "diamond" disc coal-cutter, driven by compressed air, which also became popular on the European continent.Besides the considerable economic advantages it created, the use of machinery for mining coal increased the safety of working in hard and thin seams. The improvement of safety in mining technology was always his primary concern, and as a result of his inventions and his many publications he became the leading figure in the British coal mining industry at the beginning of the twentieth century; safety lamps still carry his name. In 1885 he invented a firedamp detector, and following a severe explosion in 1886 he concentrated on coal-dust experiments. From the information he obtained of the effect of stone-dust on a coal-dust explosion he proposed the stone-dust remedy to prevent explosions of coal-dust. As a result of discussions which lasted for decades and after he had been entrusted with the job of conducting the British coal-dust experiments, in 1921 an Act made it compulsory in all mines which were not naturally wet throughout to treat all roads with incombustible dust so as to ensure that the dust always consisted of a mixture containing not more than 50 per cent combustible matter. In 1901 Garforth erected a surface gallery which represented the damaged roadways of a mine and could be filled with noxious fumes to test self-contained breathing apparata. This gallery formed the model from which all the rescue-stations existing nowadays have been developed.[br]Principal Honours and DistinctionsKnighted 1914. LLD Universities of Birmingham and Leeds 1912. President, Midland Institute 1892–4. President, The Institution of Mining Engineers 1911–14. President, Mining Association of Great Britain 1907–8. Chairman, Standing Committee on Mining, Advisory Council for Scientific and Industrial Research. Fellow of the Geological Society of London. North of England Institute of Mining and Mechanical Engineers Greenwell Silver Medal 1907. Royal Society of Arts Fothergill Gold Medal 1910. Medal of the Institution of Mining Engineers 1914.Bibliography1901–2, "The application of coal-cutting machines to deep mining", Transactions of the Federated Institute of Mining Engineers 23: 312–45.1905–6, "A new apparatus for rescue-work in mines", Transactions of the Institution of Mining Engineers 31:625–57.1902, "British Coal-dust Experiments". Paper communicated to the International Congress on Mining, Metallurgy, Applied Mechanics and Practical Geology, Dusseldorf.Further ReadingGarforth's name is frequently mentioned in connection with coal-holing, but his outstanding achievements in improving safety in mines are only described in W.D.Lloyd, 1921, "Memoir", Transactions of the Institution of Mining Engineers 62:203–5.WKBiographical history of technology > Garforth, William Edward
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114 Hunter, John
SUBJECT AREA: Medical technology[br]b. 14 (registered 13) February 1728 East Kilbride, Lanarkshire, Scotlandd. 16 October 1793 London, England[br]Scottish surgeon and anatomist, pioneer of experimental methods in medicine and surgery.[br]The younger brother of William Hunter (1718–83), who was of great distinction but perhaps of slightly less achievement in similar fields, he owed much of his early experience to his brother; William, after a period at Glasgow University, moved to St George's Hospital, London. In his later teens, John assisted a brother-in-law with cabinet-making. This appears to have contributed to the lifelong mechanical skill which he displayed as a dissector and surgeon. This skill was particularly obvious when, after following William to London in 1748, he held post at a number of London teaching hospitals before moving to St George's in 1756. A short sojourn at Oxford in 1755 appears to have been unfruitful.Despite his deepening involvement in the study of comparative anatomy, facilitated by the purchase of animals from the Tower menagerie and travelling show people, he accepted an appointment as a staff surgeon in the Army in 1760, participating in the expedition to Belle Isle and also serving in Portugal. He returned home with over 300 specimens in 1763 and, until his appointment as Surgeon to St George's in 1768, was heavily involved in the examination of this and other material, as well as in studies of foetal testicular descent, placental circulation, the nature of pus and lymphatic circulation. In 1772 he commenced lecturing on the theory and practice of surgery, and in 1776 he was appointed Surgeon-Extraordinary to George III.He is rightly regarded as the founder of scientific surgery, but his knowledge was derived almost entirely from his own experiments and observations. His contemporaries did not always accept or understand the concepts which led to such aphorisms as, "to perform an operation is to mutilate a patient we cannot cure", and his written comment to his pupil Jenner: "Why think. Why not trie the experiment". His desire to establish the aetiology of gonorrhoea led to him infecting himself, as a result of which he also contracted syphilis. His ensuing account of the characteristics of the disease remains a classic of medicine, although it is likely that the sequelae of the condition brought about his death at a relatively early age. From 1773 he suffered recurrent anginal attacks of such a character that his life "was in the hands of any rascal who chose to annoy and tease him". Indeed, it was following a contradiction at a board meeting at St George's that he died.By 1788, with the death of Percival Pott, he had become unquestionably the leading surgeon in Britain, if not Europe. Elected to the Royal Society in 1767, the extraordinary variety of his collections, investigations and publications, as well as works such as the "Treatise on the natural history of the human teeth" (1771–8), gives testimony to his original approach involving the fundamental and inescapable relation of structure and function in both normal and disease states. The massive growth of his collections led to his acquiring two houses in Golden Square to contain them. It was his desire that after his death his collection be purchased and preserved for the nation. It contained 13,600 specimens and had cost him £70,000. After considerable delay, Par-liament voted inadequate sums for this purpose and the collection was entrusted to the recently rechartered Royal College of Surgeons of England, in whose premises this remarkable monument to the omnivorous and eclectic activities of this outstanding figure in the evolution of medicine and surgery may still be seen. Sadly, some of the collection was lost to bombing during the Second World War. His surviving papers were also extensive, but it is probable that many were destroyed in the early nineteenth century.[br]Principal Honours and DistinctionsFRS 1767. Copley Medal 1787.Bibliography1835–7, Works, ed. J.F.Palmer, Philosophical Transactions of the Royal Society, London.MG -
115 Kompfner, Rudolph
[br]b. 16 May 1909 Vienna, Austriad. 3 December 1977 Stanford, California, USA[br]Austrian (naturalized English in 1949, American in 1957) electrical engineer primarily known for his invention of the travelling-wave tube.[br]Kompfner obtained a degree in engineering from the Vienna Technische Hochschule in 1931 and qualified as a Diplom-Ingenieur in Architecture two years later. The following year, with a worsening political situation in Austria, he moved to England and became an architectural apprentice. In 1936 he became Managing Director of a building firm owned by a relative, but at the same time he was avidly studying physics and electronics. His first patent, for a television pick-up device, was filed in 1935 and granted in 1937, but was not in fact taken up. In June 1940 he was interned on the Isle of Man, but as a result of a paper previously sent by him to the Editor of Wireless Engineer he was released the following December and sent to join the group at Birmingham University working on centimetric radar. There he worked on klystrons, with little success, but as a result of the experience gained he eventually invented the travelling-wave tube (TWT), which was based on a helical transmission line. After disbandment of the Birmingham team, in 1946 Kompfner moved to the Clarendon Laboratory at Oxford and in 1947 he became a British subject. At the Clarendon Laboratory he met J.R. Pierce of Bell Laboratories, who worked out the theory of operation of the TWT. After gaining his DPhil at Oxford in 1951, Kompfner accepted a post as Principal Scientific Officer at Signals Electronic Research Laboratories, Baldock, but very soon after that he was invited by Pierce to work at Bell on microwave tubes. There, in 1952, he invented the backward-wave oscillator (BWO). He was appointed Director of Electronics Research in 1955 and Director of Communications Research in 1962, having become a US citizen in 1957. In 1958, with Pierce, he designed Echo 1, the first (passive) satellite, which was launched in August 1960. He was also involved with the development of Telstar, the first active communications satellite, which was launched in 1962. Following his retirement from Bell in 1973, he continued to pursue research, alternately at Stanford, California, and Oxford, England.[br]Principal Honours and DistinctionsPhysical Society Duddell Medal 1955. Franklin Institute Stuart Ballantine Medal 1960. Institute of Electrical and Electronics Engineers David Sarnoff Award 1960. Member of the National Academy of Engineering 1966. Member of the National Academy of Science 1968. Institute of Electrical and Electronics Engineers Medal of Honour 1973. City of Philadelphia John Scott Award 1974. Roentgen Society Silvanus Thompson Medal 1974. President's National medal of Science 1974. Honorary doctorates Vienna 1965, Oxford 1969.Bibliography1944, "Velocity modulated beams", Wireless Engineer 17:262.1942, "Transit time phenomena in electronic tubes", Wireless Engineer 19:3. 1942, "Velocity modulating grids", Wireless Engineer 19:158.1946, "The travelling-wave tube", Wireless Engineer 42:369.1964, The Invention of the TWT, San Francisco: San Francisco Press.Further ReadingJ.R.Pierce, 1992, "History of the microwave tube art", Proceedings of the Institute of Radio Engineers: 980.KF -
116 Ohm, Georg Simon
SUBJECT AREA: Electricity[br]b. 16 March 1789 Erlangen, near Nuremberg, Germanyd. 6 July 1854 Munich, Germany[br]German physicist who laid the foundations of electrical science with his discovery of Ohm's Law.[br]Given the same first name as his father, Johann, at his baptism, Ohm was generally known by the name of Georg to avoid confusion. While still a child he became interested in science and learned many of his basic skills from his father, a mechanical engineer. After basic education he attended the Gymnasium at Erlangen for a year, then in 1805 he entered the University of Erlangen. Probably for financial reasons, he left after three terms in 1806 and obtained a post as a mathematics tutor at a school in Gottstadt, Switzerland, where he may well have begun to experiment with electrical circuits. In 1811 he returned to Erlangen. He appears to have obtained his doctorate in the same year. After studying physics for a year, he became a tutor at the Studienanstalt (girls' secondary school) at Bamberg in Bavaria. There, in 1817, he wrote a book on the teaching of geometry in schools, as a result of which King Freidrich Wilhelm III of Prussia had him appointed Oberlehrer (Senior Master) in Mathematics and Physics at the Royal Consistory in Cologne. He continued his electrical experiments and in 1826 was given a year's leave of absence to concentrate on this work, which culminated the following year in publication of his "Die galvanische Kette", in which he demonstrated his now-famous Law, that the current in a resistor is proportional to the applied voltage and inversely proportional to the resistance. Because he published only a theoretical treatment of his Law, without including the supporting experimental evidence, his conclusions were widely ignored and ridiculed by the eminent German scientists of his day; bitterly disappointed, he was forced to resign his post at the Consistory. Reduced to comparative poverty he took a position as a mathematics teacher at the Berlin Military School. Fortunately, news of his discovery became more widely known, and in 1833 he was appointed Professor at the Nuremberg Polytechnic School. Two years later he was given the Chair of Higher Mathematics at the University of Erlangen and the position of State Inspector of Scientific Education. Honoured by the Royal Society of London in 1841 and 1842, in 1849 he became Professor of Physics at Munich University, apost he held until his death.[br]Principal Honours and DistinctionsRoyal Society Copley Medal 1841. FRS 1842.Bibliography1817, "Grundlinien zu einer zweckmàssigen Behandlung der Geometric als hohern Bildungsmittels an vorbereitenden Lehranstalt".1827, "Die galvanische Kette, mathematische bearbeit".Further ReadingF.E.Terman, 1943, Radio Engineers' Handbook, New York: McGraw-Hill, Section 3 (for circuit theory based on Ohm's Law).See also: Thévénin, Léon CharlesKF -
117 Talbot, William Henry Fox
SUBJECT AREA: Photography, film and optics[br]b. 11 February 1800 Melbury, Englandd. 17 September 1877 Lacock, Wiltshire, England[br]English scientist, inventor of negative—positive photography and practicable photo engraving.[br]Educated at Harrow, where he first showed an interest in science, and at Cambridge, Talbot was an outstanding scholar and a formidable mathematician. He published over fifty scientific papers and took out twelve English patents. His interests outside the field of science were also wide and included Assyriology, etymology and the classics. He was briefly a Member of Parliament, but did not pursue a parliamentary career.Talbot's invention of photography arose out of his frustrating attempts to produce acceptable pencil sketches using popular artist's aids, the camera discura and camera lucida. From his experiments with the former he conceived the idea of placing on the screen a paper coated with silver salts so that the image would be captured chemically. During the spring of 1834 he made outline images of subjects such as leaves and flowers by placing them on sheets of sensitized paper and exposing them to sunlight. No camera was involved and the first images produced using an optical system were made with a solar microscope. It was only when he had devised a more sensitive paper that Talbot was able to make camera pictures; the earliest surviving camera negative dates from August 1835. From the beginning, Talbot noticed that the lights and shades of his images were reversed. During 1834 or 1835 he discovered that by placing this reversed image on another sheet of sensitized paper and again exposing it to sunlight, a picture was produced with lights and shades in the correct disposition. Talbot had discovered the basis of modern photography, the photographic negative, from which could be produced an unlimited number of positives. He did little further work until the announcement of Daguerre's process in 1839 prompted him to publish an account of his negative-positive process. Aware that his photogenic drawing process had many imperfections, Talbot plunged into further experiments and in September 1840, using a mixture incorporating a solution of gallic acid, discovered an invisible latent image that could be made visible by development. This improved calotype process dramatically shortened exposure times and allowed Talbot to take portraits. In 1841 he patented the process, an exercise that was later to cause controversy, and between 1844 and 1846 produced The Pencil of Nature, the world's first commercial photographically illustrated book.Concerned that some of his photographs were prone to fading, Talbot later began experiments to combine photography with printing and engraving. Using bichromated gelatine, he devised the first practicable method of photo engraving, which was patented as Photoglyphic engraving in October 1852. He later went on to use screens of gauze, muslin and finely powdered gum to break up the image into lines and dots, thus anticipating modern photomechanical processes.Talbot was described by contemporaries as the "Father of Photography" primarily in recognition of his discovery of the negative-positive process, but he also produced the first photomicrographs, took the first high-speed photographs with the aid of a spark from a Leyden jar, and is credited with proposing infra-red photography. He was a shy man and his misguided attempts to enforce his calotype patent made him many enemies. It was perhaps for this reason that he never received the formal recognition from the British nation that his family felt he deserved.[br]Principal Honours and DistinctionsFRS March 1831. Royal Society Rumford Medal 1842. Grand Médaille d'Honneur, L'Exposition Universelle, Paris, 1855. Honorary Doctorate of Laws, Edinburgh University, 1863.Bibliography1839, "Some account of the art of photographic drawing", Royal Society Proceedings 4:120–1; Phil. Mag., XIV, 1839, pp. 19–21.8 February 1841, British patent no. 8842 (calotype process).1844–6, The Pencil of Nature, 6 parts, London (Talbot'a account of his invention can be found in the introduction; there is a facsimile edn, with an intro. by Beamont Newhall, New York, 1968.Further ReadingH.J.P.Arnold, 1977, William Henry Fox Talbot, London.D.B.Thomas, 1964, The First Negatives, London (a lucid concise account of Talbot's photograph work).J.Ward and S.Stevenson, 1986, Printed Light, Edinburgh (an essay on Talbot's invention and its reception).H.Gernsheim and A.Gernsheim, 1977, The History of Photography, London (a wider picture of Talbot, based primarily on secondary sources).JWBiographical history of technology > Talbot, William Henry Fox
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118 Waterhouse, Major-General James
SUBJECT AREA: Photography, film and optics[br]b. 1841d. 28 September 1922[br]English military man and photographer.[br]Waterhouse spent most of his career in the Indian Army. In 1861–2 he was commissioned to photograph the tribes of central India, and over the next few years visited many parts of the subcontinent. In November 1866, after working for five months in the Great Trigonometrical Survey learning the process of photozincography (an early photomechanical process used chiefly for map making), he took charge of photographic operations at the Surveyor-General's office in Calcutta, a post he held until retiring in 1897. During this time he developed many improvements in the photomechanical methods used for reproduction in his office. He also experimented with methods of colour-sensitizing photographic materials, experimenting with eosine dye and publishing in 1875 the fact that this made silver halide salts sensitive to yellow light. He also discovered that gelatine dry plates could be made sensitive to red and infra-red illumination by treatment with alizarine blue solution.He continued his researches upon his retirement and return to England in 1897, and made a special study of the early history of the photographic process. His work on dye sensitizing brought him the Progress Medal of the Royal Photographic Society, and the Vienna Photographic Society awarded him the Voigtländer Medal for researches in scientific photography. One invention often erroneously attributed to him is the Waterhouse stop, the use of a series of perforated plates as a means of adjusting the aperture of a photographic lens. This was described in 1858 by a John Waterhouse, being his only contribution to photography.BCBiographical history of technology > Waterhouse, Major-General James
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119 WSEAS
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120 Американское научное общество стеклодувов
Silicates: American Scientific Glassblowers SocietyУниверсальный русско-английский словарь > Американское научное общество стеклодувов
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