Highly efficient wavelength-tunable anti-Stokes signal conversion by phase-matched four-wave mixing in the second-order mode of photonic crystal fiber

J. H. Yuan; X. Z. Sang; C. X. Yu; X. J. Xin; G. Y. Zhou; S. G. Li; L. T. Hou

doi:10.1007/s00340-011-4581-5

Highly efficient wavelength-tunable anti-Stokes signal conversion by phase-matched four-wave mixing in the second-order mode of photonic crystal fiber

J. H. Yuan^*, X. Z. Sang, C. X. Yu, X. J. Xin, G. Y. Zhou, S. G. Li, L. T. Hou

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Using the photonic crystal fiber (PCF) with zero dispersion wavelengths of the fundamental mode and the second-order mode at 985 nm and 885 nm designed and fabricated in our lab, the anti-Stokes signals from 586.5 to 558 nm are efficiently generated in the second-order mode. When the pump working wavelength λ ₀ increases from 830 to 880 nm and the input average power P _in reduces from 43 to 25 mW, the output power of anti-Stokes signal increases 1.76 times, the power ratio of anti-Stokes signal at 558 nm to the residual pump component at 880 nm is estimated as 5:1, and the maximal conversion efficiency P _as/P _p0 can be up to 36%. The possible reasons for the difference from theoretical results are discussed. The combined effects of the interval between the pump working wavelength and zero dispersion wavelength and the input power on the signal conversion process are analyzed.

Original language	English
Pages (from-to)	117-123
Number of pages	7
Journal	Applied Physics B: Lasers and Optics
Volume	104
Issue number	1
DOIs	https://doi.org/10.1007/s00340-011-4581-5
Publication status	Published - Jul 2011
Externally published	Yes

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title = "Highly efficient wavelength-tunable anti-Stokes signal conversion by phase-matched four-wave mixing in the second-order mode of photonic crystal fiber",

abstract = "Using the photonic crystal fiber (PCF) with zero dispersion wavelengths of the fundamental mode and the second-order mode at 985 nm and 885 nm designed and fabricated in our lab, the anti-Stokes signals from 586.5 to 558 nm are efficiently generated in the second-order mode. When the pump working wavelength λ 0 increases from 830 to 880 nm and the input average power P in reduces from 43 to 25 mW, the output power of anti-Stokes signal increases 1.76 times, the power ratio of anti-Stokes signal at 558 nm to the residual pump component at 880 nm is estimated as 5:1, and the maximal conversion efficiency P as/P p0 can be up to 36%. The possible reasons for the difference from theoretical results are discussed. The combined effects of the interval between the pump working wavelength and zero dispersion wavelength and the input power on the signal conversion process are analyzed.",

author = "Yuan, {J. H.} and Sang, {X. Z.} and Yu, {C. X.} and Xin, {X. J.} and Zhou, {G. Y.} and Li, {S. G.} and Hou, {L. T.}",

year = "2011",

month = jul,

doi = "10.1007/s00340-011-4581-5",

language = "English",

volume = "104",

pages = "117--123",

journal = "Applied Physics B: Lasers and Optics",

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T1 - Highly efficient wavelength-tunable anti-Stokes signal conversion by phase-matched four-wave mixing in the second-order mode of photonic crystal fiber

AU - Yuan, J. H.

AU - Sang, X. Z.

AU - Yu, C. X.

AU - Xin, X. J.

AU - Zhou, G. Y.

AU - Li, S. G.

AU - Hou, L. T.

PY - 2011/7

Y1 - 2011/7

N2 - Using the photonic crystal fiber (PCF) with zero dispersion wavelengths of the fundamental mode and the second-order mode at 985 nm and 885 nm designed and fabricated in our lab, the anti-Stokes signals from 586.5 to 558 nm are efficiently generated in the second-order mode. When the pump working wavelength λ 0 increases from 830 to 880 nm and the input average power P in reduces from 43 to 25 mW, the output power of anti-Stokes signal increases 1.76 times, the power ratio of anti-Stokes signal at 558 nm to the residual pump component at 880 nm is estimated as 5:1, and the maximal conversion efficiency P as/P p0 can be up to 36%. The possible reasons for the difference from theoretical results are discussed. The combined effects of the interval between the pump working wavelength and zero dispersion wavelength and the input power on the signal conversion process are analyzed.

AB - Using the photonic crystal fiber (PCF) with zero dispersion wavelengths of the fundamental mode and the second-order mode at 985 nm and 885 nm designed and fabricated in our lab, the anti-Stokes signals from 586.5 to 558 nm are efficiently generated in the second-order mode. When the pump working wavelength λ 0 increases from 830 to 880 nm and the input average power P in reduces from 43 to 25 mW, the output power of anti-Stokes signal increases 1.76 times, the power ratio of anti-Stokes signal at 558 nm to the residual pump component at 880 nm is estimated as 5:1, and the maximal conversion efficiency P as/P p0 can be up to 36%. The possible reasons for the difference from theoretical results are discussed. The combined effects of the interval between the pump working wavelength and zero dispersion wavelength and the input power on the signal conversion process are analyzed.

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Highly efficient wavelength-tunable anti-Stokes signal conversion by phase-matched four-wave mixing in the second-order mode of photonic crystal fiber

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