PACS numbers

52.80.Pi High-frequency and RF discharges 84.40.−x Radiowave and microwave
  1. V.G. Dudnikov “Surface-plasma method for the production of negative ion beams62 1233–1267 (2019)
    01.65.+g, 29.25.Ni, 52.80.Pi (all)
  2. Advances in astronomy (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 27 February 2013)56 704–737 (2013)
    01.10.Fv, 04.50.−h, 04.70.−s, 07.57.−c, 07.87.+v, 12.10.Kt, 84.40.−x, 89.20.−a, 95.36.+x, 96.12.−a, 96.30.Gc, 97.10.Bt, 97.60.Lf, 97.80.Jp, 98.62.Js, 98.70.Qy, 98.80.−k (all)
  3. A.V. Ipatov “A new generation interferometer for fundamental and applied research56 729–737 (2013)
    01.10.Fv, 07.57.−c, 84.40.−x, 89.20.−a (all)
  4. E.A. Kral’kina “Low-pressure radio-frequency inductive discharge and possibilities of optimizing inductive plasma sources51 493–512 (2008)
    52.40.Fd, 52.50.−b, 52.80.Pi (all)
  5. V.F. Kravchenko, A.A. Kuraev, A.K. Sinitsyn “Nonsynchronous interactions50 489–511 (2007)
    07.57.−c, 41.20.Jb, 84.40.−x (all)
  6. G.A. Mesyats “Similarity laws for pulsed gas discharges49 1045–1065 (2006)
    52.80.−s, 52.80.Dy, 52.80.Pi (all)
  7. V.A. Kotel’nikov “On the transmission capacity of ’ether’ and wire in electric communications49 736–744 (2006)
    01.10.Fv, 84.40.−x, 89.70.+c (all)
  8. B.E. Chertok “V A Kotel’nikov and his role in the development of space radio electronics in our country49 761–765 (2006)
    01.10.Fv, 01.60.+q, 84.40.−x (all)
  9. V.A. Vanke “Transverse electron-beam waves for microwave electronics48 917–937 (2005)
    07.50.−e, 41.75.−i, 84.40.−x, 84.40.Fe (all)
  10. G.A. Mesyats, M.I. Yalandin “High-power picosecond electronics48 211–229 (2005)
    52.59.−f, 52.80.−s, 84.30.Jc, 84.40.−x, 84.70.+p (all)
  11. O.N. Krokhin “The early years of quantum electronics47 1045–1048 (2004)
    01.65.+g, 42.55.−f, 84.40.−x (all)
  12. Yu.M. Popov “On the history of the invention of the injection laser47 1068–1070 (2004)
    01.65.+g, 42.55.−f, 84.40.−x (all)
  13. A.E. Reznikov, V.V. Kopeikin et alDevelopment of apparatus and data processing methods for electromagnetic subsurface probing and experiments with their practical implementation43 521–524 (2000)
    07.05.Kf, 07.57.−c, 07.90.+c, 84.40.−x (all)
  14. G.A. Askar’yan, G.M. Batanov et alAftereffects of microwave discharges in the stratosphere31 957–959 (1988)
    84.40.Ua, 52.80.Pi, 92.60.Xg (all)
  15. S.A. Kazantsev, N.Ya. Polinovskaya et alPolarization of atomic ensembles in ionized gases31 785–809 (1988)
    52.80.Hc, 52.80.Pi (all)
  16. V.N. Ochkin, N.G. Preobrazhenskii et alOptogalvanic effect in plasmas and gases29 260–280 (1986)
    52.70.Kz, 52.80.Hc, 33.20.Vq, 52.80.Pi, 32.80.Rm (all)
  17. M.V. Kuzelev, A.A. Rukhadze et alRelativistic plasma UHF electronics28 724–726 (1985)
    52.27.Ny, 52.75.−d, 52.35.Hr, 52.25.−b, 84.40.−x (all)
  18. N.E. Alekseevskii, A.F. Andreev et alPetr Leonidovich Kapitsa (Obituary)28 108–110 (1985)
    01.60.+q, 52.80.Pi (all)
  19. G.A. Askar’yan, V.A. Kholodilov “Interaction of a microwave beam with a liquid: energy conversion, possible applications27 885–886 (1984)
    84.40.−x, 52.80.Pi (all)
  20. Yu.P. Raizer “Propagation of discharges and maintenance of a Dense plasma by electromagnetic fields15 688–707 (1973)
    52.35.Tc, 52.25.Fi, 52.25.Os, 52.80.Pi, 82.33.Vx (all)
  21. Yu.P. Raizer “High-frequency high-pressure induction discharge and the electrodeless plasmotron12 777–791 (1970)
    52.80.Pi, 52.75.−d, 52.25.−b (all)
  22. B.Z. Katsenelenbaum “Quasioptical methods of generation and transmission of millimeter waves7 385–400 (1964)
    84.40.−x, 42.15.−i, 42.79.Bh (all)
  23. K.F. Kudu “A high-frequency demonstration indicator of radiation7 331–331 (1964)
    52.80.Pi, 84.30.Ng, 01.50.My (all)
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