Hollow-solid composite multi-core photonic crystal fiber and its laser amplification method

A photonic crystal fiber, solid technology, applied in the direction of laser, cladding fiber, optical waveguide light guide, etc., can solve the problem that the signal laser is difficult to gain and amplify, the laser pulse energy cannot be amplified, and the laser mode field and the doped medium cannot effectively overlap, etc. problem, to achieve the effect of excellent beam quality and improved withstand power

Active Publication Date: 2018-12-28
LASER FUSION RES CENT CHINA ACAD OF ENG PHYSICS
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Problems solved by technology

[0006] The high threshold characteristic of the hollow-core photonic crystal fiber benefits from the extremely small power ratio in the quartz glass, but at the same time, it also causes the laser mode field and the doped medium to not overlap effectively, making it difficult for the signal laser to be amplified
Therefore, the hollow-core photonic crystal fiber can only be used as a transmission medium at present, and cannot amplify the laser pulse energy, and the transmitted high peak power laser needs to be generated by other types of lasers

Method used

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  • Hollow-solid composite multi-core photonic crystal fiber and its laser amplification method

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Embodiment 1

[0026] Such as figure 1 As shown, a hollow-solid composite multi-core photonic crystal fiber comprises from outside to inside: protective layer 1, cladding 2, solid gain core 3 and hollow core 41, cladding 2 around the hollow core 41 Micro-air holes 42 are formed, and the cladding 2 with the micro-air holes 42 and the hollow core 41 form the same structure as the hollow photonic crystal fiber. The hollow core 41 is used to transmit high-energy signal laser light, and the micro-air holes 42 are used to limit the signal laser light. In the hollow core 41 , in this embodiment, preferably, the hollow core photonic crystal fiber is a kagomé structured fiber, and the inside of the hollow core 41 is in a vacuum state, which can further increase the withstand power and damage threshold of the hollow core 41 . The cladding 2 around the solid gain core 3 is provided with regularly arranged micro-holes 31, and the cladding 2 with the micro-holes 31 and the solid gain core 3 form the same...

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Abstract

The invention discloses a hollow-solid composite multi-core photonic crystal fiber and a laser amplifying method thereof. The fiber comprises a protection layer, a covering layer and a fiber core successively from exterior to interior. The fiber core comprises a solid gain fiber core and a hollow fiber core. The covering layer and the hollow fiber core form a structure which is the same as a hollow photonic crystal fiber. According to the invention, by combining the hollow photonic crystal fiber and a multi-core photonic crystal fiber, and combining the high damage threshold of the hollow photonic crystal fiber and the nonlinear beam combination of the multi-core photonic crystal fiber, advantages of them are completely kept; use restriction of them is overcome; laser energy will not be restrained by the damage threshold of the multi-layered photonic crystal fiber; and the single-module laser pulse peak power is amplified and output to the GW level or the average power is amplified and output to the 100kW level.

Description

technical field [0001] The invention relates to the technical field of high-power fiber lasers, in particular to a hollow-solid composite multi-core photonic crystal fiber and a laser amplification method thereof. Background technique [0002] In 1961, E.Snitzer and others proposed the concept of fiber laser, and in 1966, Gao Kun and others pointed out the direction for the development of extremely low loss optical fiber. Since then, fiber laser has been widely used in various fields due to its unique advantages such as high reliability, high compactness, high energy efficiency and maintenance-free. In 1988, E. Snitzer and others proposed the concept of double-clad fiber, which significantly increased the pump power that the fiber could absorb and coupled, and provided the possibility for high-power laser amplification. The emergence of single-mode or few-mode large-mode-field optical fibers in the late 1990s increased the nonlinear threshold and damage threshold of optical...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G02B6/02H01S3/067
CPCG02B6/02328G02B6/02338G02B6/02347G02B6/02357H01S3/06754
Inventor 张永亮邓颖王少奇康民强薛海涛叶海仙郑建刚张雄军李明中张君许党朋田小程胡东霞郑奎兴粟敬钦朱启华魏晓峰郑万国
Owner LASER FUSION RES CENT CHINA ACAD OF ENG PHYSICS
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