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Kvantovaya Elektronika, 2014, Volume 44, Number 2, Pages 102–121 (Mi qe15150)  

This article is cited in 11 scientific papers (total in 11 papers)

Invited paper

Power optics

V. V. Apollonov

Prokhorov General Physics Institute of the Russian Academy of Sciences, Moscow
References:
Abstract: By using the theory we developed in the early 1970s, a broad range of phenomena is considered for an optical surface of a solid body that is exposed to radiation arbitrarily varying in time and producing temperature fields, thermoelastic stresses and thermal deformations on the surface layer. The examination is based on the relations (which are similar to Duhamel's integral formula from the theory of heat conduction) between the quantities characterising the thermal stress state in any nonstationary regimes of energy input into a solid. A peculiar feature of the analysis of the thermal stress state in this case consists in the fact that this relation comprises time as a parameter, which in turn is a consequence of incoherence of the quasi-stationary problem of thermoelasticity. This phenomenon is particularly important for the optics of high-power, high-pulse repetition rate lasers, which are being actively developed. In the review, we have recently published in Laser Physics, the thermal stress state of a solid is analysed. In this state, time is treated as an independent variable used in differentiation. Such an approach greatly reduces the applicability of the method. The review published contains data on the use of capillary porous structures made of various materials with different degrees of the surface development. Moreover, such structures can be efficiently employed to increase the heat exchange at a temperature below the boiling point of the coolant. In the present review we discuss the dependences of the limiting laser intensities on the duration of a pulse or a pulse train, corresponding to the three stages of the state of the reflecting surface and leading to unacceptable elastic deformations of the surface, to the plastic yield of the material accompanied by the formation of residual stresses and to the melting of the surface layer. We also analyse the problem of heat exchange in the surface layer with a liquid metal coolant pumped through it. The theoretical estimates are compared with the experimental data. We discuss the issues related to the technology of fabrication of power optics elements based on materials with a porous structure, of lightweight highly stable large optics based on highly porous materials, multi-layer honeycomb structures and silicon carbide, as well as problems of application of physical and technical fundamentals of power optics in modern cutting-edge technology.
Keywords: power optics element, static power optics, adaptive power optics, surface deformation, stress field, porous structures, hydraulic characteristics, nomograms of surface deformation, powder and fibrous structures, stability parameters, thermal parameters, liquid metal cooling, large optics, highly porous cellular materials, silicon carbide optics.
Received: 01.02.2013
Revised: 11.10.2013
English version:
Quantum Electronics, 2014, Volume 44, Issue 2, Pages 102–121
DOI: https://doi.org/10.1070/QE2014v044n02ABEH015150
Bibliographic databases:
Document Type: Article
PACS: 42.79.-e, 42.55.-f
Language: Russian


Citation: V. V. Apollonov, “Power optics”, Kvantovaya Elektronika, 44:2 (2014), 102–121 [Quantum Electron., 44:2 (2014), 102–121]
Linking options:
  • https://www.mathnet.ru/eng/qe15150
  • https://www.mathnet.ru/eng/qe/v44/i2/p102
  • This publication is cited in the following 11 articles:
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
    Квантовая электроника Quantum Electronics
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    Abstract page:567
    Full-text PDF :225
    References:65
    First page:25
     
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