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• Mapping
  D. Kouznetsov, D. Rohrlich. Quantum noise in the mapping of phase space. [[Optics and Spectroscopy]], July 1997, v.83, N6, p.909-913</ref>.
  14 KB (2,275 words) - 18:25, 30 July 2019
• Халтура
  [[IEEE Journal of Selected Topics in Quantum Electronics]], Diode-pumped continuous-wave and passively mode-locked Yb:GSO laser. [[Optics Express]], volume=14, pages=686-695
  25 KB (774 words) - 18:33, 30 July 2019
• Place of science in the human knowledge
  ...once. The formalism had constructed for Physics (for needs of the Quantum Optics and the Laser Science), but it applies also to other sciences. In this work Before quantum mechanics, the fundamental possibility of describing any system in terms of
  100 KB (14,715 words) - 16:21, 31 October 2021
• Место науки в человеческом знании
  ...etsov. Quantum fluctuations do not annihilate the optical soliton. Quantum Optics, <b>4</b> 221-227 (1992) http://www.maik.rssi.ru/cgi-bin/search.pl?type=abstract&name=optics&number=10&year=99&page=594 или http://www.ils.uec.ac.jp/~dima/PAPERS/gom
  111 KB (2,581 words) - 16:54, 17 June 2020
• Active mirror
  ...large-aperture medium-repetition rate Nd:glass amplifier|journal=[[Applied Optics]]|volume=1837|pages=351–361| year=1981|doi=10.1364/AO.20.000351}}</ref> |journal=[[IEEE Journal of Selected Topics in Quantum Electronics|IEEE J. of Selected Topics in QE]]
  15 KB (2,320 words) - 14:31, 20 June 2013
• Quantum reflection
  '''Quantum reflection''' is physical phenomenon of [[specular reflection]] of a matter This phenomenon can be described in terms of [[quantum mechanics]] and has no classical analogy.
  16 KB (2,453 words) - 18:26, 30 July 2019
• Fourier transform
  In [[Quantum mechanics]], function \(A\) may have sense of the [[wave function]] in the ...he second order characterization of ultrashort pulses. [[Journal of Modern Optics]], v.46, No.15, p.2069-2077 (1999).<!-- DOI: 10.1080/09500349908231393 !-->
  11 KB (1,501 words) - 18:44, 30 July 2019
• FFT
  ...v, D.Kh.Morozov. Density of turbulence-induced phase dislocations. Applied Optics, 1998, v.37, No.21, p.4525-4535. ...to double-clad fiber amplifiers: Numerical simulations. [[IEEE Journal of Quantum Electronics]], 2004, v.40, No.9, p.1301-1305.
  6 KB (1,010 words) - 13:23, 24 December 2020
• Conservation of energy-momentum
  ==Quantum mechanics== ==Optics==
  3 KB (488 words) - 18:25, 30 July 2019
• Singapore 2011
  The use of the Yb-doped materials with low quantum defect by [[Chinese Optics Letters]], 2007, v.5, p.S240-S242
  8 KB (1,147 words) - 18:44, 30 July 2019
• Coherent atomic energetics
  ...mic energetics[[ is concept of the non-thermal use of energy of metastable quantum states. ...ry results of the limits of the single–mode approximation in the Quantum Optics had been published in the past century
  10 KB (1,625 words) - 18:44, 30 July 2019
• Institute for Laser Science
  | journal=[[Optics Letters]] ...and ceramics. Since then, the Institute has carried out experiments with [[quantum reflection]] of cold excited [[neon]] atoms from [[silicon]] surfaces.
  12 KB (1,757 words) - 07:01, 1 December 2018
• Paraxial approximation
  ...raxial approximation. However, this approximation still works well for the optics of atomic waves. [[Optics]], [[Diffraction]]
  3 KB (496 words) - 18:25, 30 July 2019
• Absorbing Schroedinger
  The [[Absorbing Schroedinger]] describes the evolution of the quantum state of a particle slightly coupled to other particles, [[environment]], g </ref>. The Absorbing Schroedinger describes the [[quantum reflection]] of particles from the region of their absorption.
  15 KB (2,070 words) - 18:47, 30 July 2019
• Guiding of waves between absorbing walls
  The Absorbing Schroedinger describes the evolution of the quantum state of a particle slightly coupled to many other particles, [[environment [[Quantum reflection]],
  5 KB (743 words) - 18:47, 30 July 2019
• History
  ...literature) for analysis of articles (and the presentations) about quantum optics and other [[laser science]].
  8 KB (1,149 words) - 21:13, 9 March 2021
• Noeter Theorem in mechanics
  ...], but also to the [[field theory]], and, in rapricular, to the [[paraxial optics]] and the [[Navier-Stokes equation]]. In Optics, the conservation of quasi-energy prohibits the [[quantum annihilation of the optical solution]]; the conservation momentum in the me
  10 KB (1,317 words) - 18:25, 30 July 2019
• Кот Шредингера
  is [[quantum state]] that can be represented as superposition of two (o [[Optics and Spectroscopy]], 1999, v.87, No.4, pp.594-602.
  5 KB (146 words) - 18:33, 30 July 2019
• Nandan gun
  quantum communications and quantum computing [10-20]. Quantum Computation
  6 KB (903 words) - 18:44, 30 July 2019
• Superfunctions
  This notation is borrowed from the [[Quantum mechanics]], where \(P^2(\psi)=P(P(\psi))\), but never \(P(\psi)^2\). quantum stability of the optical soliton, suggested
  15 KB (2,166 words) - 20:33, 16 July 2023
• Hermite Gauss mode
  [[Quantum mechanics]] [[Category:Optics]]
  8 KB (1,216 words) - 18:43, 30 July 2019
• Hermite polynomial
  [[Category:Optics]] [[Category:Quantum mechanics]]
  4 KB (628 words) - 18:47, 30 July 2019
• Oscillator function
  [[Category:Optics]] [[Category:Quantum mechanics]]
  6 KB (846 words) - 18:47, 30 July 2019
• Parabolic coordinates
  [[Atomic optics]], [[Quantum mechanics]],
  3 KB (470 words) - 18:43, 30 July 2019
• Quantum decay
  [[Quantum decay]] is specific kind of evolution of a multilevel [[quantum system]], characterised in the following: ==Application of the concept of quantum decay==
  3 KB (518 words) - 18:44, 30 July 2019
• Ленингад
  ...etsov. Quantum fluctuations do not annihilate the optical soliton. Quantum Optics, 1992, v.4, p.221-227.
  40 KB (491 words) - 07:21, 1 December 2018
• Тщеславие Кузнецова
  D.Yu.Kouznetsov. Quantum fluctuations do not annihilate the optical soliton. -- Quantum Optics, 1992, v.4, p.221-227.
  5 KB (210 words) - 07:34, 1 December 2018
• Уничтожение
  ...etsov. Quantum fluctuations do not annihilate the optical soliton. Quantum Optics: Journal of the European Optical Society Part B, Volume 4, Number 4, p.221-
  1 KB (55 words) - 07:35, 1 December 2018
• Place of science
  ...of researchers, as it happened in the USSR with the theory of relativity, quantum mechanics, cybernetics, genetics and other sciences. Quantum annihilation of the optical soliton. <ref>
  101 KB (14,271 words) - 20:58, 25 September 2020
• Place of Science in the Human Knowledge
  ...once. The formalism had constructed for Physics (for needs of the Quantum Optics and the Laser Science), but it applies also to other sciences. In this work Before quantum mechanics, the fundamental possibility of describing any system in terms of
  101 KB (14,846 words) - 00:35, 21 March 2023
• Kestus
  ...en collected from various sources for analysis of results about optics and quantum mechanics, id est "Laser Science". Then they happen to be useful in general ...n suggested to classify, evaluate the articles about quantum mechanics and optics ("Laser science"); then the axioms happened to be useful in math <ref name=
  88 KB (12,153 words) - 10:20, 26 February 2023
• DimaHistory
  После её публикации в журнале «[[Quantum Optics]]»<ref> D.Yu.Kouznetsov. Quantum fluctuations do not annihilate the optical soliton.
  29 KB (652 words) - 23:45, 16 July 2022