[1] P. Pringsheim. Zwei bemerkungen über den unterschied von lumineszenz- und temperaturstrahlung. Z. Phys., 57, 739-746(1929).

[2] M. Sheik-Bahae, R. I. Epstein. Optical refrigeration. Nat. Photonics, 1, 693-699(2007).

[3] A. Kastler. Quelques suggestions concernant la production optique et la détection optique d’une inégalité de population des niveaux de quantifigation spatiale des atomes. Application à l’expérience de Stern et Gerlach et à la résonance magnétique. J. Phys. Radium, 11, 255-265(1950).

[4] R. I. Epstein, M. I. Buchwald, B. C. Edwards, T. R. Gosnell, C. E. Mungan. Observation of laser-induced fluorescent cooling of a solid. Nature, 377, 500-503(1995).

[5] J. Fernandez, A. J. Garcia-Adeva, R. Balda. Anti-Stokes laser cooling in bulk erbium-doped materials. Phys. Rev. Lett., 97, 033001(2006).

[6] N. J. Condon, S. R. Bowman, S. P. O’Connor, R. S. Quimby, C. E. Mungan. Optical cooling in Er³⁺:KPb₂Cl₅. Opt. Express, 17, 5466-5472(2009).

[7] B. Zhong, J. Yin, Y. Jia, L. Chen, Y. Hang, J. Yin. Laser cooling of Yb³⁺-doped LuLiF₄ crystal. Opt. Lett., 39, 2747-2750(2014).

[8] A. Volpi, G. Cittadino, A. Di Lieto, M. Tonelli. Anti-Stokes cooling of Yb-doped KYF₄ single crystals. J. Lumin., 203, 670-675(2018).

[9] D. V. Seletskiy, S. Melgaard, M. Sheik-Bahae, S. Bigotta, A. DiLieto, M. Tonelli. Laser cooling of a semiconductor load using a Yb:YLF optical refrigerator. Proc. SPIE, 7614, 761409(2010).

[10] S. D. Melgaard, A. R. Albrecht, M. P. Hehlen, M. Sheik-Bahae. Solid-state optical refrigeration to sub-100 Kelvin regime. Sci. Rep., 6, 20380(2016).

[11] A. Gragossian, J. Meng, M. Ghasemkhani, A. R. Albrecht, M. Sheik-Bahae. Astigmatic Herriott cell for optical refrigeration. Opt. Eng., 56, 011110(2016).

[12] M. P. Hehlen, J. Meng, A. R. Albrecht, E. R. Lee, A. Gragossian, S. P. Love, C. E. Hamilton, R. I. Epstein, M. Sheik-Bahae. First demonstration of an all-solid-state optical cryocooler. Light Sci. Appl., 7, 15(2018).

[13] D. V. Seletskiy, R. Epstein, M. Sheik-Bahae. Laser cooling in solids: advances and prospects. Rep. Prog. Phys., 79, 096401(2016).

[14] M. Sheik-Bahae, R. I. Epstein. Laser cooling of solids. Laser Photon. Rev., 3, 67-84(2009).

[15] C. W. Hoyt, M. Sheik-Bahae, R. I. Epstein, B. C. Edwards, J. E. Anderson. Observation of anti-Stokes fluorescence cooling in thulium-doped glass. Phys. Rev. Lett., 85, 3600-3603(2000).

[16] W. Patterson, S. Bigotta, M. Sheik-Bahae, D. Parisi, M. Tonelli, R. Epstein. Anti-Stokes luminescence cooling of Tm³⁺ doped BaY₂F₈. Opt. Express, 16, 1704-1710(2008).

[17] E. E. Brown, U. Hömmerich, E. Kumi-Barimah, A. Bluiett, S. B. Trivedi. Comparative spectroscopic studies of Ho:KPb₂Cl₅, Ho:KPb₂Br₅, and Ho:YAG for 2  μm laser cooling applications. Proc. SPIE, 9380, 93800O(2015).

[18] A. Gragossian, A. Volpi, J. Meng, A. R. Albrecht, S. Rostami, M. P. Hehlen, M. Sheik-Bahae. Investigation of temperature dependence of quantum efficiency and parasitic absorption in rare-earth doped crystals. Proc. SPIE, 10550, 1055006(2018).

[19] S. Melgaard, D. Seletskiy, V. Polyak, Y. Asmerom, M. Sheik-Bahae. Identification of parasitic losses in Yb:YLF and prospects for optical refrigeration down to 80  K. Opt. Express, 22, 7756-7764(2014).

[20] P. W. France, S. F. Carter, J. M. Parker. Oxidation states of 3D transition metals in ZrF₄ glasses. Phys. Chem. Glasses, 27, 32-41(1986).

[21] B. M. Walsh. Spectroscopy and excitation dynamics of the trivalent lanthanides Tm3+ and Ho3+ in LiYF4(1995).

[22] A. Sugiyama, M. Katsurayama, Y. Anzai, T. Tsuboi. Spectroscopic properties of Yb doped YLF grown by a vertical Bridgman method. J. Alloys Compd., 408–412, 780-783(2006).

[23] S. Rostami, A. R. Albercht, M. R. Ghasemkhani, S. D. Melgaard, A. Gragossian, M. Tonelli, M. Sheik-Bahae. Optical refrigeration of Tm:YLF and Ho:YLF crystals. Proc. SPIE, 9765, 97650P(2016).

[24] S. Rostami, A. R. Albrecht, M. Tonelli, M. Sheik-Bahae. Advances in laser cooling of Tm:YLF crystals. Proc. SPIE, 10121, 1012101(2017).

[25] S. D. Melgaard. Cryogenic optical refrigeration: laser cooling of solids below 123  K(2013).

[26] D. E. McCumber. Einstein relations connecting broadband emission and absorption spectra. Phys. Rev., 136, A954-A957(1964).

[27] F. Cornacchia, A. Toncelli, M. Tonelli. 2  μm lasers with fluoride crystals: research and development. Prog. Quantum Electron., 33, 61-109(2009).

[28] S. Rostami, Z. Yang, A. R. Albrecht, A. Gragossian, M. Peysokhan, M. Ghasemkhani, A. Volpi, M. Tonelli, M. Sheik-Bahae. Advances in mid-IR solid-state optical cooling and radiation-balanced lasers. Proc. SPIE, 10550, 105500Q(2018).

[29] K. Yin, B. Zhang, G. Xue, L. Li, J. Hou. High-power all-fiber wavelength-tunable thulium doped fiber laser at 2  μm. Opt. Express, 22, 19947-19952(2014).

[30] N. Simakov, Z. Li, Y. Jung, J. M. O. Daniel, P. Barua, P. C. Shardlow, S. Liang, J. K. Sahu, A. Hemming, W. A. Clarkson, S.-U. Alam, D. J. Richardson. High gain holmium-doped fibre amplifiers. Opt. Express, 24, 13946-13956(2016).

[31] W. A. Clarkson, L. Pearson, Z. Zhang, J. W. Kim, D. Shen, A. J. Boyland, J. K. Sahu, M. Ibsen. High power thulium doped fiber lasers. Optical Fiber Communication Conference and National Fiber Optic Engineers Conference, OWT1(2009).

[32] D. J. Richardson, J. Nilsson, W. A. Clarkson. High power fiber lasers: current status and future perspectives [Invited]. J. Opt. Soc. Am. B, 27, B63-B92(2010).

[33] B. Anderson, A. Flores, J. Grosek, I. Dajani. High power Tm-doped all-fiber amplifier at 2130  nm. Conference on Lasers and Electro-Optics, SM1L.3(2017).

[34] A. F. H. Librantz, S. D. Jackson, F. H. Jagosich, L. Gomes, G. Poirier, S. J. L. Ribeiro, Y. Messaddeq. Excited state dynamics of the Ho³⁺ ions in holmium singly doped and holmium, praseodymium-codoped fluoride glasses. J. Appl. Phys., 101, 123111(2007).

[35] G.-Z. Dong, X.-L. Zhang. Role of upconversion in optical refrigeration: a theoretical study of laser cooling with Ho³⁺ doped fluoride crystals. J. Opt. Soc. Am. B, 30, 3041-3047(2013).

[36] G.-Z. Dong, X.-L. Zhang, L. Li. Energy transfer enhanced laser cooling in Ho³⁺ and Tm³⁺-codoped lithium yttrium fluoride. J. Opt. Soc. Am. B, 30, 939-944(2013).

[37] T. Kessler, C. Hagemann, C. Grebing, T. Legero, U. Sterr, F. Riehle, M. J. Martin, L. Chen, J. Ye. A sub-40-mHz-linewidth laser based on a silicon single-crystal optical cavity. Nat. Photonics, 6, 687-692(2012).

[38] O. Graydon. Payload success. Nat. Photonics, 12, 315(2018).

[39] M. P. Hehlen, M. Sheik-Bahae, R. I. Epstein. Solid-state optical refrigeration. Handbook on the Physics and Chemistry of Rare Earths, 45, 179-260(2014).

[40] G. Nemova. Laser Cooling: Fundamental Properties and Applications(2017).

[41] S. R. Bowman. Lasers without internal heat generation. IEEE J. Quantum Electron., 35, 115-122(1999).

[42] S. R. Bowman, S. O. Connor, S. Biswal, N. J. Condon. Demonstration and analysis of a high power radiation balanced laser. CLEO 2011—Laser Science to Photonic Applications, CMH4(2011).

[43] S. Rostami, A. R. Albrecht, A. Volpi, M. P. Hehlen, M. Tonelli, M. Sheik-Bahae. Tm-doped crystals for mid-IR optical cryocoolers and radiation balanced lasers(2019).

[44] G. Nemova, R. Kashyap. Radiation-balanced amplifier with two pumps and a single system of ions. J. Opt. Soc. Am. B, 28, 2191-2194(2011).

[45] J. Powers, P. Haus. Fundamentals of Nonlinear Optics(2017).