Infrared and Laser Engineering, Volume. 49, Issue 12, 20201069(2020)
LD-pumped high-repetition-rate all-solid-state femtosecond lasers (Invited)
[16] [16] Herr S, Steinmetz T, Wilken T, et al. Optical mode structure of a harmonically modelocked Yb femtosecond fiber laser[C]CLEO: 2011Laser Science to Photonic Applications. IEEE, 2011: 12.
[21] [21] https:yohei.issp.utokyo.ac.jpwksGHzLaser.html
[25] R Paschotta, L Krainer, S Lecomte. Picosecond pulse sources with multi-GHz repetition rates and high output power. New J Phys, 6, 174(2004).
[26] R Grange, M Haiml, R Paschotta. New regime of inverse saturable absorption for self-stabilizing passively mode-locked lasers. Appl Phys B, 80, 151-158(2005).
[28] [28] Ye J, Cundiff S T. Femtosecond Optical Frequency Comb: Principle, Operation Applications[M]. Switzerl: Springer Science & Business Media, 2005.
[41] M T Murphy, T Udem, R Holzwarth. High-precision wavelength calibration of astronomical spectrographs with laser frequency combs. Mon Not R Astron Soc, 380(2007).
[45] [45] Yamazoe S, Katou M, Kasamatsu T. Ultracompact Laserdiodepumped Femtosecond Solidstate Laser[ZOL]. [20200616] https:www.fujifilm.comaboutresearchrept054pdfindexff_rd054_009_en.pdf.
[49] G Genty, S Coen, J M Dudley. Fiber supercontinuum sources. J Opt Soc Am B, 24, 1771-1785(2007).
[50] [50] Pekarek S, Stumpf M C, Lecomte S, et al. Compact gigahertz frequency comb generation: how sht do the pulses need to be[C]ASSP Optical Society of America, 2012: AT5A. 2.
[54] [54] Klenner A, Golling M, Keller U. Compact gigahertz frequency combs[C]ASSL Optical Society of America, 2013: ATh3A. 1.
[56] [56] Klenner A, Golling M, Keller U. Gigahertz diodepumped Yb: CALGO laser with 60fs pulses an average output power of 3.5 W [C]CLEOLaser Science to Photonic Applications. IEEE, 2014: 12.
[61] [61] Endo M, Ozawa A, Kobayashi Y. Kerrlens modelocked Yb: KYW laser at 3.3GHz repetition rate[C]CLEO Optical Society of America, 2012: CF3L. 2.
[62] [62] Kobayashi Y, Nomura Y, Watanabe S. 1.3GHz, 20W, femtosecond chirpedpulse amplifier system[C]CLEO Optical Society of America, 2010: CMN3.
[63] M Endo, A Ozawa, Y Kobayashi. Kerr-lens mode-locked Yb: KYW laser at 4.6-GHz repetition rate. Opt Express, 20, 12181-12197(2012).
[66] [66] Endo M, Ozawa A, Sukegawa T, et al. 5.2GHz, Kerrlens modelocked Yb: Lu2O3 ceramic laser f combresolved broadb spectroscopy. [C]CLEO OSA Technical Digest (online), 2013: CTu1I. 3.
[70] Z Qing, Z Yanying, W Zhiyi. Sub-10 fs laser pulses with repetition rate of 1.1 GHz by a Ti: sapphire oscillator. Chinese Sci Bull, 20, 3649-3652(2009).
[72] Wenlong Wang, Wei Lin, Huihui Cheng. Gain-guided soliton: Scaling repetition rate of passively modelocked Yb-doped fiber lasers to 12.5 GHz. Opt Express, 27, 10438-10448(2019).
[75] [75] International Telecommunication Union. 20150912. IMT Vision—Framewk overall objectives of the future development of IMT f 2020 beyond. ITUR, M20830[EBOL]. https:www.itu.intdms_pubreciturrecmRRECM.20830201509I!!PDFE.pdf
[76] I Tomohiro, A A Eilanlou, N Yasuo. Kerr lens mode-locked Yb: Lu2O3 bulk ceramic oscillator pumped by a multimode laser diode. Jpn J Appl Phys., 54, 072703(2015).
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Li Zheng, Huibo Wang, Wenlong Tian, Dacheng Zhang, Hainian Han, Jiangfeng Zhu, Zhiyi Wei. LD-pumped high-repetition-rate all-solid-state femtosecond lasers (Invited)[J]. Infrared and Laser Engineering, 2020, 49(12): 20201069
Category: Advanced Laser Technology
Received: Sep. 12, 2020
Accepted: --
Published Online: Jan. 14, 2021
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