High Power Laser and Particle Beams, Volume. 33, Issue 11, 111005(2021)
Recent advances in mid-infrared ultrafast fiber laser technology
Figures & Tables(10)
![(a) Molecules absorption spectrum[1] and (b) atmospheric transmission windows](/Images/icon/loading.gif){kind=icon}
Fig. 1. (a) Molecules absorption spectrum[1] and (b) atmospheric transmission windows
Fig. 3. Methods for fiber laser mode-locking. The methods (a-c) have successfully mode-locked the mid-infrared fiber laser
Fig. 4. (a-d) 2,8 μm nonlinear polarization rotation based mode-locking[29]. (a) Experimental configuration; (b) direct and reconstructed output spectra; (c)autocorrelation trace; (d) second harmonic signal spectrum. (e-g) 3.5 μm nonlinear polarization rotation based mode-locking[32]. (e) Experimental setup; (f) pulse spectrum; (g) autocorrelation trace
Fig. 5. Mid-infrared ultrafast fiber lasers mode-locked by saturable absorbers. Left to right column: setup, autocorrelation trace and spectra
Fig. 6. Typical Q-switched fiber laser based on saturable absorbers
Fig. 7. Frequency shifted feedback mode-locking[72]. including pump-output power curve, output spectrum, Q-switched waveform, mode-locked waveform, autocorrelation trace and radio frequency spectrum
Fig. 8. (a-d) 70 fs pulses generation via nonlinear compression[34]. (a) Experimental setup; (b) output spectra; (c) autocorrelation trace before compression; (d) autocorrelation trace after compression. (e-h) 15.9 fs pulses generation via chirped pulse amplification and high order soliton self-compression[33]. (e) Experimental setup; (f) spectra of seed and amplified pulse; (g) spectrum of compressed pulse; (h) retrieved temporal intensity and phase of compressed pulse
Fig. 9. Mid-infrared supercontinuum generation directly pumped by mid-infrared ultrafast pulse[4]. (a) Experimental setup; (b) supercontinuum spectra pumped by different peak power
Table 1. Comparison of results of mid-infrared fiber lasers Q-switched by various saturable absorbers
View tableView in ArticleTable 1. Comparison of results of mid-infrared fiber lasers Q-switched by various saturable absorbers
saturable absorber doped rare-earth elements wavelenth/nm duration/ns frequency/kHz SNR/dB power/mW reference SNR: single-to-noise ratio; BP: black phosphorus; SWCNT: single-walled carbon nanotube graphene Er3+ 2783 1670 37 30 62 [ 53 ]SESAM Er3 2791 1680 47.6 50 317 [ 54 ]Bi2Te3 Ho3+ 2979.9 1370 81.96 37.4 327.4 [ 55 ]BP Er3+ 2779 1180 63 − 485 [ 56 ]SESAM Er3+ 2783 315 146.3 − 1010 [ 57 ]Bi2Te3 Er3+ 2791 1300 92 36 856 [ 58 ]WS2 Ho3+/Pr3+ 2867 1670 131.6 40.5 48.4 [ 59 ]Fe2+:ZnSe Er3+ 2779 742 102.9 41 822 [ 60 ]Fe2+:ZnSe Er3+ 2780 430 160.8 39 873 [ 61 ]GNS Er3+ 2800 536 125 44 454 [ 62 ]SWCNT Ho3+/Pr3+ 2837~2892 1460 131.6 40 55.8 [ 63 ]PbS Dy3+ 2710~3080 795 166.8 33 252.7 [ 64 ]MoS2 Er3+ 2754 806 70 40 140 [ 65 ]MXene Er3+ 2798 730 99.5 33.1 80 [ 66 ]Sb Er3+ 2800 1700 28.8 36.2 59 [ 52 ]PtSe2 Ho3+/Pr3+ 2865 620 238.1 30 93 [ 67 ]Fe3O4 Dy3+ 2931 1250 123 35 111 [ 68 ]InSe Er3+ 2791 423 253 43.7 712 [ 69 ]
Tools
Get Citation
Copy Citation Text
Shaodong Hou, Peiguang Yan, Shuangchen Ruan. Recent advances in mid-infrared ultrafast fiber laser technology[J]. High Power Laser and Particle Beams, 2021, 33(11): 111005
Paper Information
Category: Feature Issue on Novel Laser Technology?Overview
Received: Jul. 26, 2021
Accepted: --
Published Online: Dec. 1, 2021
The Author Email: Yan Peiguang (yanpg@szu.edu.cn)
© Copyright 2018-2021 | Chinese Laser Press.
All Rights Reserved 沪ICP备15018463号-20