Nondestructive regimes of high-temperature laser annealing of KO-1 and -5 optical ceramic by CO2 laser radiation are determined within the framework of the quasistatic uncoupled problem of thermoelasticity for an isotropic plate. The processing regime with short-time action results in a large increase of the required laser radiation power density and a decrease of the require energy density. The processing regime with long-time action results in a decrease of the required energy density. The adequacy of the computational model is checked experimentally.
Similar content being viewed by others
References
S. V. Matrenin and A. I. Slosman, Technical Ceramics [in Russian], Izd. Tomsk. Politekh. Universiteta, Tomsk (2011).
F. K. Volynets, “Optical properties and areas of application of optical ceramics,” Optiko-Mekhanich. Prom-st’, No. 9, 48 – 61 (1973).
S. S. Vil’chinskaya and V. M. Lisitsyn, Optical Materials and Technologies, Technical Ceramics [in Russian], Izd. Tomsk. Politekh. Universiteta, Tomsk (2011).
A. P. Stepanov, V. F. Valeev, V. I. Nuzhdin, et al., “Annealing of silicate glass with ion-synthesized nanoparticles of silver by excimer laser,” Zh. Tekh. Fiz., 79(10), 102 – 109 (2009).
V. M. Atamanyuk, A. F. Kovalenko, I. V. Levun, and A. V. Fedichev, “Method of processing nonmetallic materials, Patent for invention RUS 2211753,” Byull. Izobr., No. 25 (2003).
A. F. Kovalenko, “Nondestructive heat-treatment regimes for glass and ceramic plates,” Steklo Keram., No. 12, 29 – 30 (2003); A. F. Kovalenko, “Nondestructive heat-treatment regimes for glass and ceramic plates,” Glass Ceram., 60(11 – 12), 414 – 416 (2003).
A. F. Kovalenko, “Nondestructive regimes of laser pulse annealing of glass ceramic plates,” Steklo Keram., No. 7, 31 – 33 (2006); A. F. Kovalenko, “Nondestructive regimes of laser pulse annealing of glass ceramic plates,” Glass Ceram., 63(7 – 8), 242 – 244 (2006).
A. F. Kovalenko and I. V. Nikitin, “Improved determination of nondestructive regimes for laser processing of glass ceramic plates,” Steklo Keram., No. 2, 23 – 24 (2012); A. F. Kovalenko and I. V. Nikitin, “Improved determination of nondestructive regimes for laser processing of glass ceramic plates,” Glass Ceram., 69(1 – 2), 59 – 60 (2012).
A. F. Kovalenko, “Experimental setup for studying the effect of the laser pulse parameters on the fracturing of nonmetallic materials,” Prib. Tekh. Éksp., No. 4, 119 – 124 (2004).
E. A. Kolenko, Handbook of the Technology of Laboratory Experiments [in Russian], Politekhnika, St. Petersburg (1994).
V. S. Bakunov, E. S. Lukin, and E. P. Sysoev, “Creep rupture strength of magnesium oxide dense polycrystalline ceramic at temperatures to 1600°C,” Steklo Keram., No. 6, 16 – 19 (2013); V. S. Bakunov, E. S. Lukin, and E. P. Sysoev, “Creep rupture strength of magnesium oxide dense polycrystalline ceramic at temperatures to 1600°C,” Glass Ceram., 70(1 – 2), 216 – 218 (2012).
N. N. Rykalin, A. A. Uglov, I. V. Zuev, and A. N. Kokora, Handbook of Laser and Electron-Beam Processing of Materials [in Russian], Mashinostroenie, Moscow (1985).
A. A. Blistanov, V. S. Bondarenko, V. V. Chkalova, et al., Handbook of Acoustic Crystals [in Russian], Nauka, Moscow (1982).
I. N. Frantsevich, F. F. Voronov, and S. A. Bakuta, Elastic Constants and Elastic Moduli of Metals and Nonmetals [in Russian], Naukova Dumka, Kiev (1982).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Steklo i Keramika, No. 9, pp. 9 – 13, September, 2014.
Rights and permissions
About this article
Cite this article
Kovalenko, A.F. Regimes for High-Temperature Annealing for KO-1 and KO-5 Ceramics by CO2 Laser Radiation. Glass Ceram 71, 309–312 (2015). https://doi.org/10.1007/s10717-015-9676-8
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10717-015-9676-8