[1] Giesen A, Speiser J. Fifteen years of work on thin-disk lasers: results and scaling laws[J]. IEEE Journal of Selected Topics in Quantum Electronics, 13, 598-609(2007).
[3] Erhard S, Giesen A, Karszewski M, et al. Novel pump design of Yb: YAG thin disc laser f operation at room temperature with improved efficiency[C]Proceedings of the Advanced Solid State Lasers. 1999.
[4] Killi A, Zawischa I, Sutter D, et al. Current status development trends of disk laser technology[C]Proceedings of the SPIE 6871 Solid State Lasers XVII: Technology Devices. 2008: 68710L.
[5] Gottwald T, Stolzenburg C, Bauer D, et al. Recent disk laser development at Trumpf[C]Proceedings of the SPIE 8547 HighPower Lasers 2012: Technology Systems. 2012: 85470C.
[6] SvenSilvius S, Tina G, Vincent K, et al. Recent development of disk lasers at TRUMPF[C]Proceedings of the SPIE 9726 Solid State Lasers XXV: Technology Devices. 2016: 972615.
[7] Schuhmann K, Hänsch T W, Kirch K, et al. Thin-disk laser pump schemes for large number of passes and moderate pump source quality[J]. Applied Optics, 54, 9400-9408(2015).
[8] Huang Yan, Zhu Xiao, Zhu Guangzhi, et al. A multi-pass pumping scheme for thin disk lasers with good anti-disturbance ability[J]. Optics Express, 23, 4605-4613(2015).
[9] Song Enmao, Zhu Guangzhi, Wang Hailin, et al. Minimizing thermal load and stabilizing mode in Yb: YAG thin disk laser by 1030 nm multi-pass pumping[J]. IEEE Photonics Technology Letters, 32, 1011-1014(2020).
[10] Chen Hantian, Song Enmao, Dong Jing, et al. Compact thindisk multipass amplifier tolerant of strong disk thermal disttions[C]Proceedings of CLEO: Science Innovations 2020. 2020.
[11] Huang Yan. The study of pumping unifmity in thin disk lasers[D]. Wuhan: Huazhong University of Science Technology, 2016: 9093