PACS numbers

04.80.Nn Gravitational wave detectors and experiments 07.60.−j Optical instruments and equipment 42.60.−v Laser optical systems: design and operation
  1. V.V. Dudelev, E.D. Cherotchenko et alQuantum cascade lasers for the 8-μm spectral range: technology, design, and analysis67 92–98 (2024)
    42.55.Px, 42.60.−v, 78.67.Pt (all)
  2. V.D. Zvorykin “N G Basov's role in the development of excimer lasers: a half-century history from the launch of the first Xe2 laser at the Lebedev Physical Institute to modern laser systems66 1037–1058 (2023)
    42.55.Lt, 42.60.−v, 42.62.−b (all)
  3. A.P. Porfirev, A.A. Kuchmizhak et alPhase singularities and optical vortices in photonics65 789–811 (2022)
    07.60.−j, 42.62.−b, 42.70.−a, 42.79.−e, 42.82.−m, 78.20.Fm (all)
  4. P.V. Zinin, K.M. Bulatov et alRemote measurement of the temperature distribution on the surface of solids under high-power laser irradiation65 852–863 (2022)
    07.35.+k, 07.60.−j, 42.79.Jq (all)
  5. M.A. Proskurnin, V.R. Khabibullin et alPhotothermal and optoacoustic spectroscopy: state of the art and prospects65 270–312 (2022)
    07.60.−j, 42.30.Wb, 43.35.Sx, 43.35.Ud, 78.20.nb, 78.20.N−, 78.20.Pa, 81.70.Cv, 82.80.Kq, 87.19.Pp (all)
  6. E.N. Ragozin, E.A. Vishnyakov et alSoft X-ray spectrometers based on aperiodic reflection gratings and their application64 495–514 (2021)
    07.60.−j, 07.85.−m, 07.85.Fv, 07.85.Nc, 07.87.+v, 42.79.−e (all)
  7. V.N. Polkovnikov, N.N. Salashchenko et alBeryllium-based multilayer X-ray optics63 83–95 (2020)
    07.60.−j, 07.85.Fv, 42.79.−e, 68.35.Ct, 68.35.Fx, 68.47.De, 68.55.A, 68.65.Ac, 81.15.−z (all)
  8. S.Yu. Mironov, A.V. Andrianov et alSpatio-temporal shaping of photocathode laser pulses for linear electron accelerators60 1039–1050 (2017)
    29.20.−c, 29.27.Ac, 42.60.By, 42.60.−v (all)
  9. D.H. Reitze “The first detections of gravitational waves emitted from binary black hole mergers60 823–829 (2017)
    04.25.dg, 04.30.−w, 04.80.Nn, 95.55.Ym (all)
  10. V.N. Rudenko “Gravitational-wave experiment in Russia60 830–842 (2017)
    04.30.−w, 04.80.Nn, 95.55.Ym (all)
  11. G.S. Bisnovatyi-Kogan, S.G. Moiseenko “Gravitational waves and core-collapse supernovae60 843–850 (2017)
    04.80.Nn, 95.85.Sz, 97.60.Bw, 97.60.Lf (all)
  12. D.V. Kazantsev, E.V. Kuznetsov et alApertureless near-field optical microscopy60 259–275 (2017)
    07.60.−j, 07.79.Fc, 61.46.−w, 68.37.Ps, 68.65.Pq, 85.30.De, 87.64.−t (all)
  13. V.I. Pustovoit “On the direct detection of gravitational waves59 1034–1051 (2016)
    04.30.−w, 04.80.Nn, 95.55.Ym (all)
  14. V.B. Braginsky, I.A. Bilenko et alBackground to the discovery of gravitational waves59 879–885 (2016)
    04.30.−w, 04.80.Nn, 95.55.Ym (all)
  15. E.A. Khazanov “Thermooptics of magnetoactive medium: Faraday isolators for high average power lasers59 886–909 (2016)
    42.60.−v, 42.79.−e, 85.70.Sq (all)
  16. A.S. Pirozhkov, E.N. Ragozin “Aperiodic multilayer structures in soft X-ray optics58 1095–1105 (2015)
    07.60.−j, 42.30.−d, 42.79.−e (all)
  17. G.B. Malykin “Sagnac effect in ring lasers and ring resonators. How does the refraction index of the optical medium influence the sensitivity to rotation?57 714–720 (2014)
    03.30.+p, 07.60.−j, 42.60.Da (all)
  18. S.P. Vyatchanin “Parametric oscillatory instability in laser gravitational antennas55 302–305 (2012)
    04.80.Nn, 07.60.−j, 42.60.−v (all)
  19. I.A. Shcherbakov “Development history of the laser54 65–71 (2011)
    01.65.+g, 42.55.−f, 42.60.−v (all)
  20. I.M. Belousova “The laser in the USSR: the first steps54 73–75 (2011)
    01.65.+g, 42.55.−f, 42.60.−v (all)
  21. A.M. Leontovich, Z.A. Chizhikova “On the creation of the first ruby laser in Moscow54 77–85 (2011)
    01.65.+g, 42.50.−p, 42.60.−v (all)
  22. A.V. Masalov “Optical Department of the Lebedev Physical Institute: early work on lasers54 87–91 (2011)
    01.65.+g, 42.55.−f, 42.60.−v (all)
  23. Yu.M. Popov “The early history of the injection laser54 96–100 (2011)
    01.65.+g, 42.55.Px, 42.60.−v (all)
  24. A.A. Manenkov “Self-focusing of laser pulses: current state and future prospects54 100–104 (2011)
    01.65.+g, 42.60.−v, 42.65.−k (all)
  25. V.P. Tychinskii “Dynamic phase microscopy: is a “dialogue” with the cell possible?50 513–528 (2007)
    07.60.−j, 87.16.−b, 87.64.−t (all)
  26. V.E. Kurochkin “Methods and tools for the express immunoassay. A new approach to solving the problem49 965–971 (2006)
    01.10.Fv, 07.60.−j, 87.64.−t (all)
  27. O.N. Krokhin “Electric power transmission using laser radiation49 425–428 (2006)
    01.10.Fv, 42.60.−v, 42.79.Gn, 72.40.+w (all)
  28. V.B. Braginskii “Development of quantum measurement methods (Methodological notes on part of Einstein’s scientific legacy)48 595–600 (2005)
    01.70.+w, 03.65.Ta, 42.50.Xa, 04.80.Nn (all)
  29. A.A. Belyanin, D. Deppe et alNew semiconductor laser designs and the exploratory investigation of the terahertz frequency range46 986–992 (2003)
    42.55.Px, 42.60.−v (all)
  30. V.N. Lukash “Cosmological model and universe structure formation46 876–876 (2003)
    04.80.Nn, 98.80.−k (all)
  31. M.I. Lomaev, V.S. Skakun et alExcilamps: efficient sources of spontaneous UV and VUV radiation46 193–209 (2003)
    07.60.−j, 42.72.Bj, 52.80.−s (all)
  32. V.B. Braginskii “Adolescent years of experimental physics46 81–87 (2003)
    03.65.Ta, 04.30.−w, 04.80.Nn, 06.20.−f, 06.30.−k, 95.55.Ym (all)
  33. I.D. Novikov, V.P. Frolov “Black holes in the Universe44 291–305 (2001)
    04.70.−s, 04.80.Nn, 97.60.Lf, 98.62.Js (all)
  34. L.P. Grishchuk, V.M. Lipunov et alGravitational wave astronomy: in anticipation of first sources to be detected44 1–51 (2001)
    04.30.−w, 04.80.Nn, 95.55.Ym, 95.85.Sz (all)
  35. V.B. Braginskii “Gravitational-wave astronomy: new methods of measurements43 691–699 (2000)
    04.30.−w, 04.80.Nn, 95.55.Ym, 95.85.Sz (all)
  36. S.V. Ivanov, P.S. Kop’ev, A.A. Toropov “Blue-green lasers based on short-period superlattices in II-VI compounds42 399–402 (1999)
    42.60.−v, 42.60.By (all)
  37. G. Frossati “A fourth-generation cryogenic gravitational antenna37 1192–1197 (1994)
    01.10.Fv, 04.80.Nn, 95.55.Ym (all)
  38. S.A. Akhmanov “Physics of lasers, laser physics, and optical physics34 (7) 641–643 (1991)
    01.30.Vv, 42.62.Fi, 42.55.Rz, 42.60.−v, 42.65.−k, 42.50.−p (all)
  39. A.M. Prokhorov “On the twenty-fifth anniversary of the laser29 1–2 (1986)
    42.55.Ah, 42.60.−v, 42.50.−p, 84.40.Ik, 42.55.Mv, 42.65.Lm (all)
  40. V.B. Braginskii, A.B. Manukin et alSearch for Gravitational Radiation of Extraterrestrial Origin15 831–832 (1973)
    01.10.Fv, 04.80.Nn, 95.55.Ym, 98.70.Vc (all)
  41. I.L. Fabelinskii “New optical methods of studying rapid processes14 341–349 (1971)
    42.65.Re, 07.60.−j, 42.60.−v, 42.72.−g, 42.65.Hw, 42.65.Es (all)
  42. F. Gerasimov, Yu.M. Kagan et alSERGEĬ ÉDUARDOVICH FRISH (on his 70th Birthday)12 438–439 (1969)
    01.60.+q, 07.60.−j, 42.50.−p, 52.50.Jm, 51.70.+f, 32.30.−r (all)
  43. V.B. Braginskii “Gravitational radiation and the prospect of its experimental discovery8 513–521 (1966)
    04.80.Nn, 95.55.Ym, 95.30.Sf, 97.80.−d (all)
  44. S.I. Vavilov “Galileo in the history of optics7 596–616 (1965)
    07.60.−j, 42.15.−i, 95.55.Br (all)
  45. S.G. Rautian “Real spectral apparatus1 245–273 (1958)
    07.57.Ty, 07.60.−j (all)
  46. D.V. Kazantsev, E.A. Kazantseva “Scattering type apertureless scaning near-field optical microscopy”, accepted
    07.79.Fc, 68.37.Ps, 07.60.−j, 87.64.Je, 61.46.+w, 85.30.De, 68.65.Pq (all)
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