Dual-wavelength collaboratively pumping scheme for a 3.9 µm continuous-wave Ho:YLF laser

Xiaofan Jing; Xinlu Zhang; Panqiang Kang; Jinjer Huang

doi:10.1364/JOSAB.501287

Journal of the Optical Society of America B
Vol. 40,
Issue 10,
pp. 2546-2555
(2023)
•https://doi.org/10.1364/JOSAB.501287

Dual-wavelength collaboratively pumping scheme for a 3.9 µm continuous-wave Ho:YLF laser

Xiaofan Jing, Xinlu Zhang, Panqiang Kang, and Jinjer Huang

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Xiaofan Jing, Xinlu Zhang, Panqiang Kang, and Jinjer Huang, "Dual-wavelength collaboratively pumping scheme for a 3.9 µm continuous-wave Ho:YLF laser," J. Opt. Soc. Am. B 40, 2546-2555 (2023)

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About this Article
History
- Original Manuscript: July 24, 2023
- Revised Manuscript: August 27, 2023
- Manuscript Accepted: August 27, 2023
- Published: September 12, 2023

Abstract

A dual-wavelength collaboratively pumping scheme is proposed to realize the efficient operation of a 3.9 µm continuous wave Ho:YLF laser. An 888 nm laser is used to excite ions from the ${}^5{{\rm I}}_8$ ground-state manifold to the ${}^5{{\rm I}}_5$ laser’s upper manifold. Another 2.1 µm laser is used to excite ions from the ${}^5{{\rm I}}_6$ laser’s lower manifold to the short-lived ${}^5{{\rm I}}_4$ manifold to eliminate the self-terminated effect of 3.9 µm laser oscillation. Numerical simulation of 3.9 µm laser output performances is carried out, based on the developed rate equations. Simulation results indicate that the dual-wavelength collaboratively pumping scheme is feasible to realize the highly efficient output of the 3.9 µm continuous wave Ho:YLF laser. The relationship between the pump power for 888 nm and 2.1 µm laser sources is analyzed to obtain the optimal output. Furthermore, the impacts of crystal doping concentration, crystal length, output mirror transmittance, and important energy-transfer processes on the laser output performances are also analyzed. The dual-wavelength collaboratively pumping scheme provides beneficial guidance for the generation of a 3.9 µm high-power continuous-wave laser in an Ho:YLF laser.

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Parameter	Value	Reference	Parameter	Value	Reference	Parameter	Value	Reference
$τ_{5}$	$\approx 26.3 µ s$	[39]	$w_{n r 21}$	$0 s^{- 1}$	[39]	$σ_{14}$	$1 \times 10^{- 21} {c m}^{2}$	[33]
$τ_{4}$	$\approx 69.4 µ s$	[39]	$β_{54}$	0.0032	[34]	$σ_{34}$	$7.4 \times 10^{- 21} {c m}^{2}$	this work
$τ_{3}$	$\approx 2.1 m s$	[39]	$β_{53}$	0.0417	[34]	$σ_{25}$	$1.9 \times 10^{- 22} {c m}^{2}$	[36]
$τ_{2}$	$\approx 17.2 m s$	[39]	$β_{52}$	0.1813	[34]	$σ_{em}$	$1.5 \times 10^{- 20} {c m}^{2}$	[33]
$τ_{r 5}$	$1400 s^{- 1}$	[39]	$β_{51}$	0.7738	[34]	$f_{4}$	$\approx 0.235$	[33]
$τ_{r 4}$	$100 s^{- 1}$	[39]	$β_{43}$	0.0348	[34]	$f_{3}$	$\approx 0.1728$	[33]
$τ_{r 3}$	$125 s^{- 1}$	[39]	$β_{42}$	0.5649	[34]	$ω_{p 1}$	50 µm	this work
$τ_{r 2}$	$58 s^{- 1}$	[39]	$β_{41}$	0.4002	[34]	$ω_{p 2}$	50 µm	this work
$w_{n r 54}$	$3.66 \times 10^{4} s^{- 1}$	[39]	$β_{32}$	0.0902	[34]	$l_{c a v}$	100 mm	this work
$w_{n r 43}$	$1.43 \times 10^{4} s^{- 1}$	[39]	$β_{31}$	0.9098	[34]	$L$	1%	this work
$w_{n r 32}$	$350 s^{- 1}$	[39]	$β_{21}$	1	[34]	$γ$	$1 \times 10^{- 7}$	[40]

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Journal of the Optical Society of America B