[1] Meyer F, Vogel T, Ahmed S et al. Single-cycle, MHz repetition rate THz source with 66 mW of average power[J]. Optics Letters, 45, 2494-2497(2020).

[2] Picqué N, Hänsch T W. Frequency comb spectroscopy[J]. Nature Photonics, 13, 146-157(2019).

[3] Emaury F, Diebold A, Saraceno C J et al. Compact extreme ultraviolet source at megahertz pulse repetition rate with a low-noise ultrafast thin-disk laser oscillator[J]. Optica, 2, 980-984(2015).

[4] Liu X Q, Chen Q D, Guan K M et al. Dry-etching-assisted femtosecond laser machining[J]. Laser & Photonics Reviews, 11, 1600115(2017).

[5] Morin F, Druon F, Hanna M et al. Microjoule femtosecond fiber laser at 1.6 μm for corneal surgery applications[J]. Optics Letters, 34, 1991-1993(2009).

[6] Liu Y Y, Cao X, Xian A H et al. Research progress of 1 μm band period ultrafast laser[J]. Laser & Optoelectronics Progress, 59, 1100003(2022).

[7] Tian W L, Xu R, Zheng L et al. 10-W-scale Kerr-lens mode-locked Yb∶CALYO laser with sub-100-fs pulses[J]. Optics Letters, 46, 1297-1300(2021).

[8] Kim J, Song Y J. Ultralow-noise mode-locked fiber lasers and frequency combs: principles, status, and applications[J]. Advances in Optics and Photonics, 8, 465-540(2016).

[9] Dong Z K, Song Y R. Research progress of mode-locked fiber lasers based on saturable absorbers[J]. Chinese Journal of Lasers, 48, 0501006(2021).

[10] Giesen A, Hügel H, Voss A et al. Scalable concept for diode-pumped high-power solid-state lasers[J]. Applied Physics B, 58, 365-372(1994).

[11] Hao J J, Liu H Y, Chen H S et al. Progress in kerr-lens mode-locked thin disk laser oscillators[J]. Chinese Journal of Lasers, 49, 1201002(2022).

[12] Aus der Au J, Spühler G J, Südmeyer T et al. 16.2-W average power from a diode-pumped femtosecond Yb∶YAG thin disk laser[J]. Optics Letters, 25, 859-861(2000).

[13] Saltarelli F, Graumann I J, Lang L et al. Power scaling of ultrafast oscillators: 350-W average-power sub-picosecond thin-disk laser[J]. Optics Express, 27, 31465-31474(2019).

[14] Pronin O, Brons J, Grasse C et al. High-power 200 fs Kerr-lens mode-locked Yb∶YAG thin-disk oscillator[J]. Optics Letters, 36, 4746-4748(2011).

[15] Brons J, Pervak V, Fedulova E et al. Energy scaling of Kerr-lens mode-locked thin-disk oscillators[J]. Optics Letters, 39, 6442-6445(2014).

[16] Fischer J, Drs J, Modsching N et al. Efficient 100-MW, 100-W, 50-fs-class Yb∶YAG thin-disk laser oscillator[J]. Optics Express, 29, 42075-42081(2021).

[17] Peng Y N, Zhang J W, Wang Z H et al. Generation of 15 W femtosecond laser pulse from a Kerr-lens mode-locked Yb∶YAG thin-disk oscillator[J]. Chinese Physics B, 25, 094207(2016).

[18] Spence D E, Kean P N, Sibbett W. 60-fsec pulse generation from a self-mode-locked Ti: sapphire laser[J]. Optics Letters, 16, 42-44(1991).

[19] Paschotta R, Keller U. Passive mode locking with slow saturable absorbers[J]. Applied Physics B, 73, 653-662(2001).

[20] Dai L H, Liu R, Li X et al. High-efficiency, high-repetition-rate cavity-dumped Q-switched Yb∶YAG thin-disk laser based on a 72-pass pump module[J]. Optics Express, 30, 19629-19638(2022).

[21] Liu R, Gong F Q, Li X et al. Research on heat transfer characteristics of porous foam heat sink for all solid state thin disk lasers[J]. Acta Photonica Sinica, 49, 0414002(2020).

[22] Dai L H, Liu R, Gong F Q et al. Cavity-dumped nanosecond thin-disk laser with high average power[J]. Chinese Journal of Lasers, 48, 1301001(2021).

[23] Kalashnikov V L, Sorokin E, Sorokina I T. Multipulse operation and limits of the Kerr-lens mode locking stability[J]. IEEE Journal of Quantum Electronics, 39, 323-36(2003).