학술논문

Efficient Tm:LiYF4 Lasers at ${\sim}2.3~\mu$ m: Effect of Energy-Transfer Upconversion
Document Type
Periodical
Source
IEEE Journal of Quantum Electronics IEEE J. Quantum Electron. Quantum Electronics, IEEE Journal of. 55(6):1-12 Dec, 2019
Subject
Engineered Materials, Dielectrics and Plasmas
Photonics and Electrooptics
Laser excitation
Pump lasers
Laser transitions
Semiconductor lasers
Crystals
Ions
Doping
Solid-state lasers
laser transitions
mid-infrared
spectroscopy
Language
ISSN
0018-9197
1558-1713
Abstract
The 3 H 4 $ \to $ 3 H 5 transition of Thulium ions (Tm 3+ ), which features laser emission at $\sim 2.3~\mu \text{m}$ is studied in details. We revise the conditions for efficient laser operation using a rate-equation model accounting for the ground-state bleaching, cross-relaxation and energy-transfer upconversion (ETU). We show that ETU has a crucial role in reaching more than unity pump quantum efficiency (QE) for $\sim 2.3~\mu \text{m}$ Tm lasers based on highly-doped crystals. A Ti:Sapphire pumped quasi-continuous-wave 3.5 at.% Tm:LiYF 4 laser generated 0.73 W at 2306 nm with a record-high slope efficiency of 47.3% (versus the absorbed pump power, for double-pass pumping) featuring a QE of 1.27. Diode-pumping of this crystal yielded a peak output power of >2 W. The first $2.3~\mu \text{m}$ Tm waveguide laser is also reported based on Tm:LiYF 4 epitaxial layers with even higher doping of 6.2 at.% generating 0.23 W with a slope efficiency of 19.8%. The spectroscopic properties of Tm:LiYF 4 relevant for the $\sim 2.3~\mu \text{m}$ laser operation are revised as well.