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Mikhail Dyakonov

Summary

Mikhail (Michel) Dyakonov (born 1940 in Leningrad) is a Russian professor of physics at Laboratoire Charles Coulomb (L2C), Université Montpellier - CNRS in France.

Mikhail Dyakonov
Born (1940-04-29) April 29, 1940 (age 83)
Leningrad, USSR
Known forDyakonov–Perel spin relaxation mechanism
Dyakonov–Shur plasma wave instability
Dyakonov–Voigt wave
Dyakonov surface waves
Parents
RelativesDmitry Dyakonov [ru] (brother)
Yakov Magaziner [ru] (grandfather)
Scientific career
InstitutionsLaboratoire Charles Coulomb (L2C), Université Montpellier

Career edit

His name is connected with several physical phenomena: Dyakonov–Perel spin relaxation mechanism, Dyakonov–Shur plasma wave instability. In 1971, together with V.I. Perel he predicted the Spin Hall Effect, which has become a field of intense studies.

He theoretically predicted a new class of surface electromagnetic waves, now called Dyakonov surface waves (DSWs) in 1988.[1][2] Unlike other types of acoustic and electromagnetic surface waves, the DSW's existence is due to the difference in symmetry of materials forming the interface. These waves are important at the interface of a biaxial anisotropic dielectric with an isotropic medium,[3] metamaterials[4] and they have also found use in terahertz applications.[5]

Awards edit

Professor Dyakonov is a recipient of the State prize (USSR) in physics for theoretical work on spin dynamics (1976), the Frenkel prize of the St. Petersburg Physical Society for theory of streamer discharge (1992), the Ioffe prize of the Russian Academy of Sciences for the theory of hot luminescence (1993), Beller Lectureship Award from the American Physical Society (2009), and the Grand prize from the French Physical Society (2009).

Critique of quantum computers edit

Dyakonov is also well known for his critique of implementations of quantum computers.[6][7] He argues that practical quantum computers are not likely to be implemented. He says: "There is a tremendous gap between the rudimentary but very hard experiments that have been carried out with a few qubits and the extremely developed quantum-computing theory, which relies on manipulating thousands to millions of qubits to calculate anything useful. That gap is not likely to be closed anytime soon."

References edit

  1. ^ Takayama, O. et al. Dyakonov Surface Waves: A Review. Electromagnetics, 28:3, 126-145
  2. ^ Dyakonov, M. I. (April 1988). "New type of electromagnetic wave propagating at an interface" (Free PDF download). Soviet Physics JETP. 67 (4): 714. Bibcode:1988JETP...67..714D.
  3. ^ Narimanov, E.E. Dyakonov waves in biaxial anisotropic crystals. Phys. Rev. A 98, 013818 (2018)
  4. ^ Jacob, Z. and Narimanov, E.E.Optical hyperspace for plasmons: Dyakonov states in metamaterials Appl. Phys. Lett. 93, 221109 (2008)[1]
  5. ^ Moradi, M. et al. Terahertz Dyakonov surface waves in plasma metamaterials. Optics Letters, Vol. 43, Issue 3, pp. 519-522 (2018)
  6. ^ "The Case Against Quantum Computing". IEEE Spectrum. 15 November 2018. Retrieved 26 March 2022.
  7. ^ Dyakonov, Mikhail I. (2020). Will We Ever Have a Quantum Computer?. SpringerBriefs in Physics. Bibcode:2020wweh.book.....D. doi:10.1007/978-3-030-42019-2. ISBN 978-3-030-42019-2. S2CID 216107299.