“Satosi Watanabe”的意思、由来-开放百科全书

Satosi Watanabe was born on May 26, 1910, in Tokyo. He attended Gakushuuin Middle High School and Tokyo High School. In 1933, he graduated from Tokyo Imperial University in theoretical physics, where Torahiko Terada was his teacher.

The imperial government sent him to France to study. Louis de Broglie encouraged Watanabe to study thermodynamics and wave mechanics.

In 1937, he moved to Leipzig and started to study nuclear theory under Heisenberg. In the same year, Watanabe married Dorothea Dauer, a scholar of German literature.

In 1939, at the beginning of World War II, he left Germany and stayed with Niels Bohr for a time. In December, he returned to Japan with his family.

Career

In Japan, he worked at the Physical and Chemical Research Institute (Rikagaku Kenkyujo) at Tokyo Imperial University as an assistant professor, and as a physics professor at Rikkyo University. In 1950, he left for the United States.

His argument that quantum mechanics is time-asymmetric (irreversible; non-invariant under the time reversal transformation) is repeated in a number of his papers (1955; 1965; 1966; 1972). It is informal but quite correct, as a more formal proof (Holster 2003) confirms. This result means that physicists have used the wrong transformation of probability laws to represent time reversal, and the popular claims that quantum mechanics is time reversal invariant are invalid. Watanabe's argument has not been accepted by physicists or philosophers however. The assumption that quantum mechanics is time symmetric on the basis of invalid conventional proofs is almost universal in the literature on time in physics to this day.

He developed the Double Inferential Vector Formalism (DIVF),^[3] later known as the Two-state vector formalism (TSVF). The DSVF/TSVF is often interpreted as a time-symmetric interpretation of quantum mechanics (see Minority interpretations of quantum mechanics). However Watanabe was quite clear that the normal physical theory of quantum mechanics that holds for real physics is time-asymmetric. He consequently rejected the conventional view that physical time asymmetry is only explained by asymmetric boundary conditions on the universe, and claimed it is a law-like feature of quantum physics.

Time-symmetric interpretations of quantum mechanics were first suggested by Walter Schottky in 1921,^[4]^[5] and later by several other scientists. Watanabe proposed that information given by forwards evolving quantum states is not complete; rather, both forwards and backwards evolving quantum states are required to describe a quantum state: a first state vector that evolves from the initial conditions towards the future, and a second state vector that evolves backwards in time from future boundary conditions. Past and future measurements, taken together, provide complete information about a quantum system. Watanabe's work was later rediscovered by Yakir Aharonov, Peter Bergmann and Joel Lebowitz in 1964, who later renamed it the Two-state vector formalism (TSVF).^[6]

In 1956, he became a researcher at the IBM Watson Laboratory and started to build his own information theory based on quantum mechanics. He taught at Yale University and the University of Hawaii, became chairman of the International Time Academy, and was the Vice President of International Philosophy Academy.

Family

His father, Chifuyu Watanabe, was a Minister of Justice at Second Wakatsuki Cabinet. His elder brother, Takeshi Watanabe, was Vice Minister of Finance for International Affairs and director general of Asia Development Bank. His wife, Dorothea Dauer Watanabe, was a professor of German (language and literature) at the University of Hawaii. His son, Hajime Watanabe, is a Professor of Philosophy at the University of California, Santa Barbara.

See also

References

1. ^{{cite book | last = Watanabe | first = Satosi | title = Knowing and Guessing: A Quantitative Study of Inference and Information | publisher = Wiley | year = 1969 | location = New York | url=http://www.igm.hokudai.ac.jp/crg/download_files/watanabe.pdf | format=page scan | pages=376–377}}{{deadlink|date=November 2017}}
2. ^{{cite book | author=Satosi Watanabe | contribution=Une Explication Mathématique du Classement d'Objets | pages=39—76 | editor1=Stanislas I. Dockx | editor2= Paul Bernays | editor2link= Paul Bernays | title=Information and Prediction in Science | publisher=Academic Press | location=New York | year=1965 | lccn=64-24655 | oclc=522269}}
3. ^Watanabe, Satosi. "Symmetry of physical laws. Part III. Prediction and retrodiction." Reviews of Modern Physics 27.2 (1955): 179.
4. ^{{cite journal| author=Schottky, Walter | authorlink=Walter Schottky |title= Das Kausalproblem der Quantentheorie als eine Grundfrage der modernen Naturforschung überhaupt |journal= Naturwissenschaften | volume= 9 | issue =25 | pages= 492-496 |date=1921|bibcode=1921NW......9..492S |doi=10.1007/BF01494985 }}
5. ^{{cite journal| author=Schottky, Walter |title= Das Kausalproblem der Quantentheorie als eine Grundfrage der modernen Naturforschung überhaupt |journal= Naturwissenschaften | volume= 9 | issue =26 | pages= 506-511 |date=1921|bibcode=1921NW......9..506S |doi=10.1007/BF01496025 }}
6. ^Yakir Aharonov, Lev Vaidman: Protective measurements of two-state vectors, in: Robert Sonné Cohen, Michael Horne, John J. Stachel (eds.): Potentiality, Entanglement and Passion-At-A-Distance, Quantum Mechanical Studies for A. M. Shimony, Volume Two, 1997, {{ISBN|978-0792344537}}, pp. 1–8, [https://books.google.com/books?id=DsNoIcQemTsC&pg=PA2 p. 2]

Early life and education

Career

Family

See also

References

Bibliography

External links