• Faraday isolator based on the terbium aluminum garnet (TAG) ceramics;
Dmitry Zheleznov, Aleksey Starobor, Oleg Palashov, Chong Chen, and Shengming Zhou, «High-power Faraday isolators based on TAG ceramics», Optics Express, Vol. 22, Issue 3, pp. 2578-2583 (2014).
• Faraday isolator based on the TAG, doped with cerium (Ce: TAG) ceramics;
D. Zheleznov, A. Starobor, O. Palashov, H. Lin, and S. Zhou, "Improving characteristics of Faraday isolators based on TAG ceramics by cerium doping," Opt. Lett. 39, 2183-2186 (2014)
• Faraday isolator based on the terbium gallium garnet (TGG) ceramics;
Ryo Yasuhara, Ilya Snetkov, Alexey Starobor, Dmitry Zheleznov, Oleg Palashov, Efim Khazanov, Hoshiteru Nozawa, and Takagimi Yanagitani, "Terbium gallium garnet ceramic Faraday rotator for high-power laser application", Optics Letters, Vol. 39, Issue 5, pp. 1145-1148 (2014)
• Faraday isolator based on the TGG ceramics, with external compensation of thermally induced distortions.
I.L. Snetkov, R. Yasuhara, AV Starobor, and OV Palashov, "TGG ceramics based Faraday isolator with external compensation of thermally induced depolarization", Optics Express Vol. 22, Iss. 4, pp. 4144-4151 (2014)
• Faraday isolator based on the TGG ceramics, with internal compensation of thermally induced distortions.
Ryo Yasuhara, Ilya Snetkov, Alexey Starobor, and Oleg Palashov “Terbium gallium garnet ceramic-based Faraday isolator with compensation of thermally induced depolarization for high-energy pulsed lasers with kilowatt average power”, Applied Physics Letters, 105, 241104 (2014)
• Faraday isolator based on the magnetic system with a pre-given transverse inhomogeneity of the magnetic field;
E.A. Mironov, A.V. Voitovich, A.V. Starobor and O.V. Palashov, Compensation of polarization distortions in Faraday isolators by means of magnetic field inhomogeneity, Applied Optics, Vol. 53, Iss. 16 — Jun. 1, 2014 pp: 3486–3491.
• Cryogenic FI based on TGG ceramics;
A.V. Starobor, R. Yasuhara, D.S. Zheleznov, O.V. Palashov and E.A. Khazanov, "Cryogenic Faraday Isolator Based of TGG ceramics", IEEE Journal of Quantum Electronics Quantum Electronics,V.50, pp.749 - 754, 2014.
• FI based on the single crystal of terbium-scandium aluminum garnet;
E. A. Mironov and O. V. Palashov, "Faraday isolator based on TSAG crystal for high power lasers," Optics Express Vol. 22, Iss. 19, pp. 23226–23230 (2014)
• Wide-aperture FI
Snetkov I.L., Voitovich A.V., Palashov O.V., Khazanov E.A., Review of Faraday Isolators for Kilowatt Average Power Lasers, IEEE Journal of Quantum Electronics, V. 50, pp. 434 – 443, 2014
• Quantron based on the on the composite Yb:YAG/YAG active element
Kuznetsov I.I., Mukhin I.B., Silin D.E.; Vyatkin A.G.; Vadimova O.L.; Palashov O.V., “Thermal Effects in end-pumped Yb:YAG thin-disk and Yb:YAG/YAG composite active element”, IEEE J. of Quantum Electronics, Vol. 50, Issue 3, pp. 133–140 (2014)
• Upgraded cryogenic disk Yb: YAG-laser
Perevesentsev E.A., Mukhin I.B., Kuznetsov I.I., Vadimova O.L., Palashov O.V., Cryogenic disk Yb: YAG-laser with output pulses of nanosecond duration // Quantum Electronics, v .44, №5, p.448-451, 2014.
