Chinese Journal of Lasers, Volume. 45, Issue 4, 400001(2018)
Research Advances in Dual-Comb Spectroscopy
Figures & Tables(13)
Fig. 1. (a) Time domain and frequency domain diagrams for pulse electric field of ideal mode-locking laser; (b) three typical locking schemes for OFCs
Fig. 2. (a) Schematic for actively measuring principle of OFC-based FTS[25]; (b) schematic for DCS measuring principle[25]; (c) asynchronous optical sampling and measuring process in time domain; (d) multiheterodyne in frequency domain for measuring process of DCS
Fig. 4. (a) Configuration of coherent DCS[36]; (b) measured phase and transmission spectra for HCN sample[36];(c) local zoom near 195 THz in Fig.4(b), measured phase (green curve) and transmission spectra (black curve) agree well with theoretical results (dotted blue line, and offset by 0.1 rad) calculated from absorption data through Kramers-Kronig relation[36]
Fig. 5. (a) Experimental site layout of open-path multicomponent greenhouse gas online measurements with coherent DCS[59]; (b) comparison of results of greenhouse gases measured by coherent DCS with those calculated with HITRAN database[59]; (c) photograph of vehicle-borne OFC[61]
Fig. 6. (a) Adaptive DCS scheme based on tracking-recording error signal technique with FBG[37]; (b) measured results with adaptive DCS[37]
Fig. 7. (a) Schematic of adaptive DCS based on CW laser references[22]; (b) comparison of C2H2 absorption spectra respectively measured by constant and adaptive clocks sampling with those obtained by using HITRAN database[22]
Fig. 8. Configuration and measuring principle of DCS scheme based on single OFC with repetition rate tuned and time-delay-multiplexing technique[27]. (a) Configuration; (b) measuring principle
Fig. 9. (a) DCS based on single laser source with dual-output ports extract lights respectively propagating in different directions inside cavity[57]; (b) DCS with dual-wavelength mode-locked fiber laser[30]
Fig. 10. Operation principles and realization schemes for improving spectral resolution of DCS with (a) phase-modulated pulse technique[66]and (b) spectral interleave scheme[69]
Table 1. Performance indexes for reported DCS
View tableTable 1. Performance indexes for reported DCS
DCS NEA /(cm-1·Hz-1/2) F SNR /(Hz1/2)SNR Resolution /GHz Spectrum coverage CE-DCS[ 73 ]1×10-10 4.6×105 380@18 μs 4.500 20 nm@1040 nm CE-OE-DCS[ 72 ]1.5×10-8 2.9×104 189@320 s 0.203 50 GHz@1550 nm OP-DCS[ 59 ]7.3×10-10 1.4×106 588@300 s 0.100 32 nm@1620 nm LA-DCS[ 23 ]2.2×10-7 2.3×108 316000@24 h 0.100 18 THz@1560 nm A-DCS[ 22 ]4.2×10-7 1.25×107 20@467 μs 1.100 14.5 THz@1560 nm OPO-DCS[ 74 ]5.3×10-7 5.3×106 81@720 μs 6.000 10.5 THz@3 μm Raman-DCS[ 75 ]2×10-6 1.8×107 1000@296 μs 120.000 42 THz@12 μm OE-DCS[ 35 ]1.7×10-9 1.3×106 2600@52 ms 0.300 35 GHz@1550 nm MC-DCS[ 34 ]2.5×10-7 3×106 74@20 μs 22.000 4 THz@1550 nm
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Lu Qiao, Shi Lei, Mao Qinghe. Research Advances in Dual-Comb Spectroscopy[J]. Chinese Journal of Lasers, 2018, 45(4): 400001
Paper Information
Category: reviews
Received: Sep. 20, 2017
Accepted: --
Published Online: Apr. 13, 2018
The Author Email: Qinghe Mao (mqinghe@aiofm.ac.cn)
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