Solid laser

A solid-state laser and laser technology, applied to the structure/shape of optical resonators, excitation methods/devices, active dielectric materials, etc., can solve unfavorable nonlinear frequency conversion, low fundamental transverse mode efficiency, and poor output beam quality And other problems, to avoid thermal cracking, reduce thermal stress, improve the effect of output power

Inactive Publication Date: 2008-06-18
SHENZHEN UNIV
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  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

One is end-pumping, also known as longitudinal pumping. The thermal effect in the laser medium is relatively serious, and the problem of thermal cracking of the laser medium greatly limits the maximum output power of the end-pumping laser. Due to its own space limitation, it is generally only used In the range of low and medium power levels; the other is side pumping, also known as transverse pumping, whose active area is located at the edge of the laser crystal, and multi-transverse mode oscillations are prone to occur in the cavity, the output beam quality is poor, and the efficiency of the fundamental transverse mode is not high, especially It is a side-pumped module product with Nd:YAG as the laser medium, and the output laser is nonlinearly polarized light, which is not conducive to efficient nonlinear frequency conversion
The current DPSSL generally uses end-face or side-pumped methods alone, which cannot overcome the above-mentioned respective shortcomings.

Method used

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Effect test

specific Embodiment approach 1

[0021] As shown in Figure 1, a 1064nm wavelength solid-state laser combining end-pumped and side-pumped laser diodes, 1 is the fiber output end of a fiber-coupled semiconductor laser system, and outputs 808nm wavelength pump light. 2 is the pump light focusing coupling system, which focuses the pump light inside the laser medium 4. 3 is the pump end cavity mirror of the laser resonator, which can be a flat mirror, a plano-convex mirror or a plano-concave mirror, and is coated with a dielectric film with high transmission at 808nm and high reflection at 1064nm. The end-pumped laser medium 4 can be Nd:YVO 4 Crystal or Nd:GdVO 4 Crystal. 1, 2 and 4 constitute the end pump device. 5 is a laser diode array side-pumped Nd:YAG crystal laser module. 6 is the output mirror of the resonant cavity, which can be a plane mirror, a plano-convex mirror or a plano-concave mirror, which is coated with a 1064nm partially reflective dielectric film. 4 and 5 are on the optical axis of the resonant ca...

specific Embodiment approach 2

[0023] As shown in Figure 3, the cavity frequency doubled 532nm wavelength green solid-state laser combining laser diode end-pumped and side-pumped, 1 is the fiber output end of the fiber-coupled semiconductor laser system, outputting 808nm wavelength pump light. 2 is the pump light focusing coupling system, which focuses the pump light inside the laser medium 4. 3 is the pump end cavity mirror of the laser resonator, which can be a flat mirror, a plano-convex mirror or a plano-concave mirror, and is coated with a dielectric film with high transmission at 808nm and high reflection at 1064nm. The end-pumped laser medium 4 can be Nd:YVO 4 Crystal or Nd:GdVO 4 Crystal. 1, 2 and 4 constitute the end pump device. 5 is a laser diode array side-pumped Nd:YAG crystal laser module. 6 is a folding mirror with a three-mirror folding resonant cavity and a green light output mirror, which can be a flat mirror, a plano-convex mirror or a plano-concave mirror, coated with a dielectric film of 10...

specific Embodiment approach 3

[0025] As shown in Figure 3, the Raman self-frequency shifting and intracavity frequency doubling of the laser diode end-pumped and side-pumped 588nm wavelength yellow light solid-state laser, 1 is the fiber output end of the fiber-coupled semiconductor laser system, and the output 808nm wavelength pump light. 2 is the pump light focusing coupling system, which focuses the pump light inside the laser medium 4. 3 is the pump end cavity mirror of the laser resonator, which can be a flat mirror, a plano-convex mirror or a plano-concave mirror, and is coated with a dielectric film with high transmission at 808nm, high reflection at 1064nm and 1176nm. The end-pumped laser medium 4 can be Nd:YVO 4 Crystal or Nd:GdVO 4 Crystal. 1, 2 and 4 constitute the end pump device. 5 is a laser diode array side-pumped Nd:YAG crystal laser module. 6 is a folding mirror with a three-mirror folding resonant cavity and a yellow light output mirror, which can be a flat mirror, a plano-convex mirror or a ...

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Abstract

The invention discloses a solid laser, comprising a resonant cavity which is provided with at least one end surface pumping device and at least one side pumping device at the same time. The oscillation laser in the resonant cavity is generated by lasing amplification of the gain medium of the end surface pumping device and the gain medium of the side pumping device at the same time; the gain medium of the end surface pumping device and the gain medium of the side pumping device are on the same optical axis of the resonant cavity. By the mutual relevance between the lasing amplification of the end surface pumping laser medium in the resonant cavity and the lasing amplification of the side pumping laser medium in the resonant cavity, the invention has the respective advantages of the end surface pumping type and the side pumping type, has high conversion efficiency, high quality of output beam and linear polarization, greatly improves the output power, correspondingly reduces the high thermal stress which is born by the end surface pumping laser medium and avoids the occurrence of thermal cracking. If the invention is combined with nonlinear optical and Q-adjusting elements, the invention can be widely applied to the nonlinear frequency conversion lasers and pulse lasers with great power.

Description

Technical field [0001] The invention relates to a solid-state laser combining end-pumping and side-pumping technologies, and belongs to the field of laser technology and devices. Background technique [0002] The existing Laser-Diode pumped solid-state laser (DPSSL) generally has two pumping methods. One is end-pumping, also known as longitudinal pumping. The thermal effect in the laser medium is more serious, and the thermal cracking of the laser medium greatly limits the maximum output power of the end-pumped laser. Due to its own space limitations, it is generally only used In the range of low and medium power levels; the other is side pumping, which is also called lateral pumping. Its active area is located at the edge of the laser crystal. Multi-transverse mode oscillation is prone to appear in the cavity, the output beam quality is poor, and the fundamental transverse mode efficiency is not high. It is a side-pumped module product with Nd:YAG as the laser medium. The output...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01S3/09H01S3/08H01S3/16
Inventor 杜晨林阮双琛于永芹
Owner SHENZHEN UNIV
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