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    Journals >Chinese Optics Letters >Volume 22 >Issue 3 >Page 031402 > Article
    • Chinese Optics Letters
    • Vol. 22, Issue 3, 031402 (2024)
    22 kW near-diffraction-limited Yb:YAG slab laser amplifier without adaptive optics correction
    Dan Wang1、2、3、*, Ping He2, Tangjian Zhou2, Mi Li2, Yingchen Wu1、2、3, Yanan Wang2, Jianli Shang2、**, Qingsong Gao2, Kai Zhang2, Chun Tang2, and Rihong Zhu1
    Author Affiliations
  • 1School of Electronic and Optical Engineering, Nanjing University of Science and Technology, Nanjing 210094, China
  • 2Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang 430079, China
  • 3Graduate School of China Academy of Engineering Physics, Beijing 100193, China
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    DOI: 10.3788/COL202422.031402 Cite this Article Set citation alerts
    Dan Wang, Ping He, Tangjian Zhou, Mi Li, Yingchen Wu, Yanan Wang, Jianli Shang, Qingsong Gao, Kai Zhang, Chun Tang, Rihong Zhu. 22 kW near-diffraction-limited Yb:YAG slab laser amplifier without adaptive optics correction[J]. Chinese Optics Letters, 2024, 22(3): 031402 Copy Citation Text show less
    Experimental setup of Yb:YAG slab MOPA chain. P-A, preamplifier; MA, main amplifier; BS, beam shaper; PM, power meter.
    Fig. 1. Experimental setup of Yb:YAG slab MOPA chain. P-A, preamplifier; MA, main amplifier; BS, beam shaper; PM, power meter.
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    (a) Schematic of CCEPS gain module; (b) detailed scheme of pump coupling and homogenization system; (c) and (d) distributions of pumping light at the middle of the slab and the entrance, respectively.
    Fig. 2. (a) Schematic of CCEPS gain module; (b) detailed scheme of pump coupling and homogenization system; (c) and (d) distributions of pumping light at the middle of the slab and the entrance, respectively.
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    Multi-concentration-doped slabs in the preamplifier and main amplifier.
    Fig. 3. Multi-concentration-doped slabs in the preamplifier and main amplifier.
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    Micrograph of the end face of the slab. (a) and (b) 100 µm level and submicrometer level surface, respectively.
    Fig. 4. Micrograph of the end face of the slab. (a) and (b) 100 µm level and submicrometer level surface, respectively.
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    Absorption rate of films. (a) and (b) Maximum absorption rate of 300 ppm and 20 ppm, respectively.
    Fig. 5. Absorption rate of films. (a) and (b) Maximum absorption rate of 300 ppm and 20 ppm, respectively.
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    Temperature comparison of the main amplifier slab end face. (a) and (b) Maximum temperatures of 110°C and 42°C, respectively.
    Fig. 6. Temperature comparison of the main amplifier slab end face. (a) and (b) Maximum temperatures of 110°C and 42°C, respectively.
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    (a) Output power of MOPA chain and optical extraction efficiency of main amplifier; (b) comparison of the theoretical and experimental dependence of the output power and slope efficiency.
    Fig. 7. (a) Output power of MOPA chain and optical extraction efficiency of main amplifier; (b) comparison of the theoretical and experimental dependence of the output power and slope efficiency.
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    (a) OPD of one passing through the slab at the maximum output power; (b) residual OPD after quadratic fitting to eliminate defocus.
    Fig. 8. (a) OPD of one passing through the slab at the maximum output power; (b) residual OPD after quadratic fitting to eliminate defocus.
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    (a) Distribution of the expanded beam in the near field; (b) variation of output beam quality (β) in 0.5 min; (c) far field with the beam quality of 2.95.
    Fig. 9. (a) Distribution of the expanded beam in the near field; (b) variation of output beam quality (β) in 0.5 min; (c) far field with the beam quality of 2.95.
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    Dan Wang, Ping He, Tangjian Zhou, Mi Li, Yingchen Wu, Yanan Wang, Jianli Shang, Qingsong Gao, Kai Zhang, Chun Tang, Rihong Zhu. 22 kW near-diffraction-limited Yb:YAG slab laser amplifier without adaptive optics correction[J]. Chinese Optics Letters, 2024, 22(3): 031402
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