Effects of excited-state absorption on self-pulsing in Tm<sup>3+</sup>-doped fiber lasers

Yulong Tang; Jianqiu Xu

doi:10.1364/JOSAB.27.000179

Journal of the Optical Society of America B
Vol. 27,
Issue 2,
pp. 179-186
(2010)
•https://doi.org/10.1364/JOSAB.27.000179

Effects of excited-state absorption on self-pulsing in ${Tm}^{3 +}$ -doped fiber lasers

Yulong Tang and Jianqiu Xu

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Yulong Tang and Jianqiu Xu, "Effects of excited-state absorption on self-pulsing in Tm³⁺-doped fiber lasers," J. Opt. Soc. Am. B 27, 179-186 (2010)

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Table of Contents Category
- Fiber Optics and Optical Communications
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The topics in this list come from the Optics and Photonics Topics applied to this article.

About this Article
History
- Original Manuscript: September 14, 2009
- Revised Manuscript: November 11, 2009
- Manuscript Accepted: November 13, 2009
- Published: January 7, 2010

Abstract

Based on theoretical analysis and numerical simulation, the mechanism of self-pulsing operation of $2 - μ m$ ${Tm}^{3 +}$ -doped fiber lasers is explored. A simplified rate-equation model is proposed to analyze stable operation of ${Tm}^{3 +}$ -doped fiber lasers. It is shown that the continuous-wave (CW) solution does not exist for certain pump intensities when excited-state absorption (ESA) is included. In numerical simulation, four energy-transfer processes are calculated to identify the origin of self-pulsing in ${Tm}^{3 +}$ -doped fiber lasers. The phonon-assisted ESA process ${}^{3}H_{5} \to {}^{3}H_{4}$ is identified as the key factor for self-pulsing in ${Tm}^{3 +}$ -doped fiber lasers, which confirms the absence of a CW solution in the theoretical analysis. The numerical simulation gives out a regular pulse train, whose characteristics are in excellent agreement with the experimental results. The impacts of ESA cross section and pump intensity on the self-pulsing characteristics are also investigated.

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Symbol	Value
$k_{4212}$	$1.8 \times 10^{- 16} {cm}^{3} s^{- 1}$
$k_{2123}$	$1.5 \times 10^{- 18} {cm}^{3} s^{- 1}$
$k_{2124}$	$1.5 \times 10^{- 17} {cm}^{3} s^{- 1}$
$τ_{i}$	$τ_{4} = 14.2 μ s$
	$τ_{3} = 0.007 μ s$
	$τ_{2} = 340 μ s$
$β_{i j}$	$β_{43} = 0.57$
	$β_{42} = 0.051$
	$β_{32} \approx 1$
$g_{2} ∕ g_{1}$	0.04 (variable)
$σ_{e}$	$2.5 \times 10^{- 21} {cm}^{2}$
$σ_{s a}$	variable $(4 \times 10^{- 21} {cm}^{2})$
m	$8 \times 10^{- 7}$
$r_{c}$	$3.6 \times 10^{7} s^{- 1}$
$σ_{a p}$	$1 \times 10^{- 20} {cm}^{2}$
$N_{tot}$	$1.37 \times 10^{20} {cm}^{- 3}$

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Journal of the Optical Society of America B