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Gain photon crystal fiber guide and its device

A photonic crystal fiber and waveguide technology, applied in optical waveguides, laser parts, lasers, etc., can solve the problems of not meeting practical application requirements, obvious nonlinear effects, and large laser power loss, etc. Heat dissipation characteristics, improving reliability and stability, and improving quality

Active Publication Date: 2009-02-18
FENGHUO COMM SCI & TECH CO LTD
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  • Abstract
  • Description
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  • Application Information

AI Technical Summary

Problems solved by technology

[0006] At present, high-power fiber lasers mostly use conventional double-clad gain fibers. This fiber laser has the following technical problems that are difficult to solve. For example, expanding its mode field diameter is one of the main ways to increase the laser power of a fiber laser, but increasing the mode The diameter will bring some negative effects, such as the decrease of beam quality and the increase of bending loss. In order to increase the laser power of the fiber, the conventional double-clad gain fiber increases the mode field diameter of the fiber. In order to ensure the beam quality, it has to be reduced. The numerical aperture of the fiber core not only brings great difficulty to the process, but also it is impossible for this technology to increase the mode field greatly. In addition, when the mode field diameter is increased, the bending loss increases sharply, resulting in optical power leakage. Even the optical fiber is damaged and cannot work normally
[0007] U.S. Patent US20050105867 and Chinese Patent CN200480033979.7 describe an active photonic bandgap fiber. The core of the fiber is air, and the fusion loss with other fibers is relatively large, and the fiber of this invention uses surface mode to transmit laser light. The loss is large and cannot well meet the needs of practical applications
Chinese patent 200510025561.8 describes an active large-core single-mode double-clad photonic crystal fiber. The fiber uses inner air holes to achieve endless single-mode characteristics, thereby improving the beam quality of fiber lasers. However, the fiber has a large bending loss. The nonlinear effect is obvious, and the multi-mode pump power cannot be effectively converted into single-mode laser power.

Method used

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  • Gain photon crystal fiber guide and its device
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  • Gain photon crystal fiber guide and its device

Examples

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Effect test

Embodiment 1

[0048] The improved chemical vapor deposition (MCVD) process is used to manufacture ytterbium ion (thulium, neodymium, holmium, praseodymium, erbium, lanthanum and other rare earth ions can also be doped) optical fiber core rod, and the rare earth doping concentration is above 6000ppm. Then, a 400±10 μm rare earth-doped quartz glass cylinder is made by drawing at a high temperature of about 2200 ° C on a wire drawing tower. The relative refractive index difference of the rare earth-doped part is between 0.61% and 2.2%, in this case it is 0.61% , The ratio of the diameter of the rare earth ion doped part to the diameter of the rare earth doped quartz glass cylinder is between 0.08 and 0.52, in this example it is 0.18. Plasma Chemical Vapor Deposition (PCVD) technology is used to manufacture high-purity quartz glass rods, and then drawn into 800±10μm high-purity quartz glass cylinders at a high temperature of 2200°C on a wire drawing tower. Use the PCVD process to prepare a germ...

Embodiment 2

[0050] The improved chemical vapor deposition (MCVD) process is used to manufacture ytterbium ion (can also be doped with thulium, neodymium, holmium, praseodymium, erbium, lanthanum and other rare earth ions) optical fiber core rod, the rare earth doping concentration is above 8000ppm, and then in wire drawing A rare earth-doped quartz glass cylinder of 400±10 μm is made by pulling down at a high temperature of about 2200°C on the tower. The relative refractive index difference of the rare earth-doped part is between 0.61% and 2.2%, in this case it is 0.61%. Doped with rare earth ions The ratio of the partial diameter to the diameter of the entire cylinder is between 0.08 and 0.52, in this case 0.32. Plasma Chemical Vapor Deposition (PCVD) technology is used to manufacture high-purity quartz glass rods, and then drawn into 800±10μm high-purity quartz glass cylinders at a high temperature of 2200°C on a wire drawing tower. A germanium-doped quartz glass rod with a core relativ...

Embodiment 3

[0052] The improved chemical vapor deposition (MCVD) process is used to manufacture ytterbium ion (can also be doped with thulium, neodymium, holmium, praseodymium, erbium, lanthanum and other rare earth ions) optical fiber core rod, the rare earth doping concentration is above 8000ppm, and then in wire drawing A rare earth-doped quartz glass cylinder of 400±10 μm is made by pulling down at a high temperature of about 2200°C on the tower. The relative refractive index difference of the rare earth-doped part is between 0.61% and 2.2%, in this case it is 0.98%. Doped with rare earth ions The ratio of the partial diameter to the diameter of the entire cylinder is between 0.08 and 0.52, in this case 0.39. Plasma Chemical Vapor Deposition (PCVD) technology is used to manufacture high-purity quartz glass rods, and then drawn into high-purity quartz glass cylinders of 410±10 μm on a wire drawing tower at a high temperature of 2200 °C. A germanium-doped quartz glass rod with a core re...

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Abstract

The invention relates to a gain photon crystal optical fiber waveguide, which is composed of a core layer and a coating layer which surrounds the core layer. The inner coating layer of the optical fiber comprise solid microstructure point lattice which is formed by germanium-doped silica column, and forms outer bandgap of the gain optical fiber, the function thereof is that the multimode pump light can be strictly restricted in a second fiber core region which is provided with rare earth dopant ion, and improves the utilizing efficiency of the pump light; the second fiber core of the optical fiber is composed of the solid microstructure point lattice which is formed the rare earth ion silica column to form the inner bandgap of the gain optical fiber, the function thereof is that through the multimode pump light, the generated laser light can be strictly restricted in a first fiber core region which is formed by high pure silica glass. Adopting the solid gain photon crystal optical fiber can greatly improve the utilization efficiency of the pump light, improve beam quality of output laser light, enhance output power of the optical fiber laser, and reduce nonlinear effect of the high-power laser device.

Description

technical field [0001] The invention relates to a gain photonic crystal optical waveguide, in particular to a rare earth-doped photonic bandgap optical waveguide in the application field of high-power lasers, and a fiber laser manufactured by using the gain photonic crystal optical waveguide. Background technique [0002] With the rapid development of energy optoelectronic technologies such as semiconductor laser pumping and laser coupling, high-power fiber lasers have achieved unprecedented technological progress. Ytterbium-doped, erbium-doped, erbium-ytterbium co-doped, thulium-doped, and neodymium-doped various new fiber lasers have been widely used. Multimode pumping technology has developed from the initial end-pump technology to the current side-pump technology, from single-pump technology to multi-pump combination technology; from incoherent to laser coherent technology; the power of fiber lasers has also changed from the initial milliwatt level Developed to kilowatt...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G02B6/02G02B6/036H01S3/067H01S3/00
Inventor 陈伟李诗愈王彦亮雷道玉罗文勇胡鹏王冬香胡福明
Owner FENGHUO COMM SCI & TECH CO LTD
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