Manfred von Ardenne explained

Manfred von Ardenne
Birth Date:20 January 1907
Birth Place:Hamburg, German Empire
Death Place:Dresden, Saxony, Germany
Nationality:German
Fields:Applied Physics
Workplaces:TU Dresden
Known For:Soviet program of nuclear weapons
Scanning electron microscope
Scanning transmission electron microscopy
Isotope separation
Cathode-ray tube
Duoplasmatron
Awards:Stalin Prize (1947, 1953)
National Prize of East Germany (1958, 1965)
Lenin Medal (1970)
Colani Design France Prize (1993)

Manfred baron von Ardenne (pronounced as /de/; 20 January 190726 May 1997) was a German researcher and applied physicist and inventor. He took out approximately 600 patents in fields including electron microscopy, medical technology, nuclear technology, plasma physics, and radio and television technology. From 1928 to 1945, he directed his private research laboratory Forschungslaboratorium für Elektronenphysik. For ten years after the World War II, Ardenne was one of many of the German nuclear physicists in the former Soviet program of nuclear weapons, and was honored with the Stalin Prize by the former Soviet Union.

Upon his return to the then East Germany, he started another private engineering firm, Forschungsinstitut Manfred von Ardenne. Ardenne is seen as one of the main inventors of the television.[1] [2]

Career

Early years

The stormy life of von Ardenne's grandmother, Elisabeth von Ardenne (1853–1952), is said to have been be the inspiration for Effi Briest by Theodor Fontane, one of the most famous German realist novels.

Born in 1907 in Hamburg to a wealthy aristocratic family, Ardenne was the oldest of five children. In 1913, Ardenne's father, assigned to the Kriegsministerium, moved to Berlin. From Ardenne's earliest youth, he was intrigued by any form of technology, and this was fostered by his parents. Ardenne's early education was at home through private teachers. In Berlin, from 1919, Ardenne attended the Realgymnasium, where he pursued his interests in physics and technology. In a school competition, he submitted models of a camera and an alarm system, for which he was awarded first place.[3] [4]

In 1923, at the age of 15, he received his first patent for an electronic tube with multiple (three) systems in a single tube for applications in wireless telegraphy. At this time, Ardenne prematurely left the Gymnasium to pursue the development of radio engineering with the entrepreneur Siegmund Loewe, who became his mentor. Loewe built the inexpensive Loewe-Ortsempfänger OE333 with Ardenne's multiple system electronic tube. In 1925, from patent sales and publication income, Ardenne substantially improved the broadband amplifier (resistance-coupled amplifier), which was fundamental to the development of television and radar.[3]

Without an Abitur, because he did not graduate from the Gymnasium, Ardenne entered university-level study of physics, chemistry, and mathematics. After four semesters, he left his formal studies, due to the inflexibility of the university system, and educated himself; he became an autodidact and devoted himself to applied physics research.[3]

In 1928, he came into his inheritance with full control as to how it could be spent, and he established his private research laboratory Forschungslaboratorium für Elektronenphysik,[5] in Berlin-Lichterfelde, to conduct his own research on radio and television technology and electron microscopy. He invented the scanning electron microscope.[6] [7] He financed the laboratory with income he received from his inventions and from contracts with other concerns. For example, his research on nuclear physics and high-frequency technology was financed by the Reichspostministerium (RPM, Reich Postal Ministry), headed by Wilhelm Ohnesorge. M von Ardenne attracted top-notch personnel to work in his facility, such as the nuclear physicist Fritz Houtermans, in 1940. Ardenne also conducted research on isotope separation. The small list of equipment Ardenne had in the laboratory is impressive for a private laboratory. For example, when on 10 May 1945 he was visited by NKVD Colonel General V. A. Makhnjov, accompanied by Soviet physicists Isaak Kikoin, Lev Artsimovich, Georgy Flyorov, and V. V. Migulin (of the Russian Alsos operation), they praised the research being conducted and the equipment, including an electron microscope, a 60-ton cyclotron, and plasma-ionic isotope separation installation.[3] [8] [9]

At the Berlin Radio Show in August 1931, Ardenne gave the world's first public demonstration of a television system using a cathode ray tube for both transmission and reception. (Ardenne never developed a camera tube, using the CRT instead as a flying-spot scanner to scan slides and film.)[10] [11] [12] Ardenne achieved his first transmission of television pictures on 24 December 1933, followed by test runs for a public television service in 1934. The world's first electronically scanned television service then started in Berlin in 1935, the Fernsehsender Paul Nipkow, culminating in the live broadcast of the 1936 Summer Olympic Games from Berlin to public places all over Germany.[3]

In 1937, Ardenne developed the scanning transmission electron microscope. During World War II, he took part in the study and application of radar.[3]

In 1941 the "" of the "Preußische Akademie der Wissenschaften" was awarded to Ardenne, and in January 1945, he received the title of "Reichsforschungsrat" (Empire Research Advisor).[13]

In the Soviet Union

Von Ardenne, Gustav Hertz, Nobel laureate and director of Research Laboratory II at Siemens, Peter Adolf Thiessen, ordinarius professor at the Humboldt University of Berlin and director of the Kaiser-Wilhelm Institut für physikalische Chemie und Elektrochemie (KWIPC) in Berlin-Dahlem, and Max Volmer, ordinarius professor and director of the Physical Chemistry Institute at the Berlin Technische Hochschule, had made a pact. The pact was a pledge that whoever first made contact with the Soviets would speak for the rest. The objectives of their pact were threefold: (1) Prevent plunder of their institutes, (2) Continue their work with minimal interruption, and (3) Protect themselves from prosecution for any political acts of the past.[14] Before the end of World War II, Thiessen, a member of the NSDAP, had Communist contacts.[15] On 27 April 1945, Thiessen arrived at von Ardenne's institute in an armored vehicle with a major of the Soviet Army, who was also a leading Soviet chemist, and they issued Ardenne a protective letter (Schutzbrief).[16]

All four of the pact members were taken to the Soviet Union. Von Ardenne was made head of Institute A,[17] in Sinop,[18] [19] a suburb of Sukhumi. In his first meeting with Lavrentij Beria, von Ardenne was asked to participate in the Soviet atomic bomb project, but von Ardenne quickly realized that participation would prohibit his repatriation to Germany, so he suggested isotope enrichment as an objective, which was agreed to.

Goals of Ardenne's Institute A included: (1) Electromagnetic separation of isotopes, for which von Ardenne was the leader, (2) Techniques for manufacturing porous barriers for isotope separation, for which Peter Adolf Thiessen was the leader, and (3) Molecular techniques for separation of uranium isotopes, for which Max Steenbeck was the leader; Steenbeck was a colleague of Hertz at Siemens.

Others at Institute A included Ingrid Schilling, Alfred Schimohr, Gerhard Siewert, and Ludwig Ziehl.[20] By the end of the 1940s, nearly 300 Germans were working at the institute, and they were not the total work force.[21]

Hertz was made head of Institute G,[22] in Agudseri (Agudzery),[18] [19] about 10 km southeast of Sukhumi and a suburb of Gul’rips (Gulrip'shi); after 1950, Hertz moved to Moscow. Volmer went to the Nauchno-Issledovatel'skij Institut-9 (NII-9, Scientific Research Institute No. 9),[23] in Moscow; he was given a design bureau to work on the production of heavy water.[24] In Institute A, Thiessen became leader for developing techniques for manufacturing porous barriers for isotope separation.[25]

At the suggestion of authorities, Ardenne eventually shifted his research from isotope separation to plasma research directed towards controlled nuclear fusion.[26]

In 1947, Ardenne was awarded a Stalin Prize for his development of a table-top electron microscope. In 1953, before his return to Germany, he was awarded a Stalin Prize, first class, for contributions to the atomic bomb project; the money from this prize, 100,000 Rubles, was used to buy the land for his private institute in East Germany. According to an agreement that Ardenne made with authorities in the Soviet Union soon after his arrival, the equipment which he brought to the Soviet Union from his laboratory in Berlin-Lichterfelde was not to be considered as "reparations" to the Soviet Union. Ardenne took the equipment with him in December 1954 when he returned to the then East Germany.[3] [27]

Return to (East) Germany

After Ardenne's arrival in the Deutsche Demokratische Republik (DDR), he became "Professor für elektrotechnische Sonderprobleme der Kerntechnik" (Professor of electrotechnical special problems of Nuclear Technology) at the Technische Hochschule Dresden. He also founded his research institute, "Forschungsinstitut Manfred von Ardenne", in Dresden, which with over 500 employees became a unique institution in East Germany as a leading research institute that was privately run. However it collapsed with substantial debts after German reunification in 1991 and re-emerged as Von Ardenne Anlagentechnik GmbH. Ardenne twice won the GDR's National Prize.[3]

In 1957, Ardenne became a member of the "Forschungsrat" of the DDR. In that year, he developed an endoradiosonde for medical diagnostics. In 1958, he was awarded the "Nationalpreis" of the DDR; the same year he became a member of the "Friedensrat". In 1959, he received a patent for the electron-beam furnace he developed. In 1961, he was selected a chairman of the "Internationale Gesellschaft für medizinische Elektronik und biomedizinische Technik". From the 1960s, he expanded his medical research and became well known for his oxygen multi-step therapy and cancer multi-step therapy.[3] [28] [29] [30]

In 1963, Ardenne became president of the "Kulturbund" of the DDR. During the period 1963 to 1989, he was a delegate to the "Volkskammer" of the DDR, as well as a member of the "Kulturbund-Fraktion".[3]

After the creation of the Dresden-Hamburg city partnership (1987), Ardenne became an honorary citizen of Dresden in September 1989.[3]

At the time of his death on 26 May 1997, Ardenne held around 600 patents.[31]

In 2002 the German "Europäische Forschungsgesellschaft Dünne Schichten" ("European Thin-Film Research Society") named an annual prize in von Ardenne's honor.[32]

Personal life

In 1937, Ardenne married Bettina Bergengruen; they had four children.[3]

Honors

Von Ardenne received many honors:[33]

Books

See also

Bibliography

External links

Notes and References

  1. Web site: Manfred von Ardenne - Herr des Fernsehens .
  2. Web site: Ein Berliner Baron erfand den Vater aller Fernseher .
  3. http://www.dhm.de/lemo/html/biografien/ArdenneManfred/ Ardenne
  4. Baron Manfred von Ardenne (1907–1997) . 10.1046/j.1365-2818.1997.2560813.x . 1997 . Mulvey . Tom . Journal of Microscopy . 188 . 2 . 94–95 . 94403861 .
  5. http://www.sachsen.de/sadra/887.htm sachen.de
  6. von Ardenne. Manfred. 1938. Das Elektronen-Rastermikroskop. Theoretische Grundlagen. Zeitschrift für Physik. 109. 9–10. 553–572. German. 10.1007/BF01341584. 1938ZPhy..109..553V . 117900835.
  7. von Ardenne. Manfred. 1938. Das Elektronen-Rastermikroskop. Praktische Ausführung. Zeitschrift für technische Physik. 19. 407–416. German.
  8. Oleynikov, 2000, 6-7.
  9. Hentschel, 1996, Appendix F; see entry for Ardenne.
  10. "Cathode radio television sender on which Baron Manfred von Ardenne has been experimenting since 1928" (photo), The New York Times, August 16, 1931, p. XX8.
  11. "Television at the Berlin Radio Exhibition", Television, October 1931, p. 310, 311, 318.
  12. Albert Abramson, Zworykin: Pioneer of Television, University of Illinois Press, 1995, p. 111.
  13. http://www.dieterwunderlich.de/Manfred_Ardenne.htm Von Ardenne
  14. Heinemann-Grüder, 2002, 44.
  15. Hentschel, 1996, Appendix F; see the entry for Thiessen.
  16. Oleynikov, 2000, 5.
  17. Institute A was used as the basis for the Sukhumi Physical-Technical Institute. See Oleynikov, 2000, 12.
  18. Oleynikov, 2000, 11-12.
  19. Naimark, 1995, 213.
  20. Maddrell, 2006, 179-180.
  21. Oleynikov, 2000, 10-11.
  22. Topics assigned to Gustav Hertz's Institute G included: (1) Separation of isotopes by diffusion in a flow of inert gases, for which Gustav Hertz was the leader, (2) Development of a condensation pump, for which Justus Mühlenpfordt was the leader, (3) Design and build a mass spectrometer for determining the isotopic composition of uranium, for which Werner Schütze was the leader, (4) Development of frameless (ceramic) diffusion partitions for filters, for which Reinhold Reichmann was the leader, and (5) Development of a theory of stability and control of a diffusion cascade, for which Heinz Barwich was the leader. See Oleynikov, 2000, 12-13 and 18. Also see Kruglov, 2002, 131.
  23. Today, NII-9 is the Bochvar All-Russian Scientific Research Institute of Inorganic Materials, Bochvar VNIINM. See Oleynikov, 2000, 4.
  24. Oleynikov, 2000, 13.
  25. Oleynikov, 2000, 11.
  26. Riehl and Seitz, 1996, 33-34.
  27. Oleynikov, 2000, 18.
  28. Manfred von Ardenne Sauerstoff- Mehrschritt- Therapie. Physiologische und technische Grundlagen (Thieme, 1987)
  29. Manfred von Ardenne, Alexander von Ardenne, and Christian Hecht Systemische Krebs-Mehrschritt-Therapie (Hippokrates, 1997).
  30. http://www.sachsen.de/sadra/887.htm sachsen.de
  31. http://www.mdr.de/mdr-figaro/hoerspiel/3989518.html MDR Figaro
  32. http://www.efds.org/index.php?sel=1&sel2=7&PHPSESSID=8475f72d67e78d5e4917363ed2b1da95&PHPSESSID=8475f72d67e78d5e4917363ed2b1da95 Manfred-von-Ardenne-Preis
  33. Manfred von Ardenne Erinnerungen, fortgeschrieben. Ein Forscherleben im Jahrhundert des Wandels der Wissenschaften und politischen Systeme 588-589 (Droste, 1997).
  34. An honorary professor has the authority to teach, but is not compelled to teach.