Application progress of the stimulated Brillouin scattering phase conjugate mirror in high power nanosecond lasers

Tianqi Wang; Zhijun Kang; Dongdong Meng; Jisi Qiu; Hao Liu

doi:10.3788/IRLA20211024

Journals >Infrared and Laser Engineering >Volume 50 >Issue 5 >Page 20211024 > Article

Infrared and Laser Engineering
Vol. 50, Issue 5, 20211024 (2021)

Application progress of the stimulated Brillouin scattering phase conjugate mirror in high power nanosecond lasers

Tianqi Wang^1、2, Zhijun Kang^1、2、*, Dongdong Meng^1、2, Jisi Qiu^1、2, and Hao Liu^1、2

Author Affiliations

¹Aerospace Information Research Institure, Chinese Academy of Sciences, Beijing 100094, China

²National Engineering Research Center for DPSSL, Beijing 100094, China

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DOI: 10.3788/IRLA20211024 Cite this Article

Tianqi Wang, Zhijun Kang, Dongdong Meng, Jisi Qiu, Hao Liu. Application progress of the stimulated Brillouin scattering phase conjugate mirror in high power nanosecond lasers[J]. Infrared and Laser Engineering, 2021, 50(5): 20211024 Copy Citation Text

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Evolution of the wavefront as the beam pass a round trip through crystal with an irregular surface. (a) Reflected by plane mirror; (b) Reflected by SBS-PCM

Fig. 1. Evolution of the wavefront as the beam pass a round trip through crystal with an irregular surface. (a) Reflected by plane mirror; (b) Reflected by SBS-PCM

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Fig. 2. Optical layout of MOPA system with SBS-PCM adopted by Zel’dovich et al^[14]

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Fig. 3. Optical layout of 690 W laser system developed by Pierre et al^[38]

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Fig. 4. Optical layout of 940 W laser system developed by Pierre et al^[39]

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Fig. 5. Optical layout of 362 W laser system developed by Kiriyama et al^[41]

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Fig. 6. Optical layout of 766 W laser system developed by Yoshida et al^[43]

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Fig. 7. MOPA system with fiber SBS-PCM developed by Eichler et al^[30]

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Fig. 8. Optical layout of 100 J level laser system developed by Wang et al^[46]

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Fig. 9. Schematic diagram of the experimental setup adopted by Zhao et al^[36]

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Fig. 10. Optical layout of 1 kW laser system developed by Fan et al^[3]

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Fig. 11. Optical layout of 550 W laser system developed by Kang et al^[47]

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Institute	Year	Properties of laser system					Properties of SBS-PCM				Ref.
Institute	Year	Output power/W	Output energy/J	Repetition rate/Hz	Pulse duration/ns	Beam quality	Medium	Input power/W	Input energy/J	Reflectivity	Ref.
America TRW	1993	100	−	100	7	1.1 DL	Freon 113	30.5	−	85%	[27]
	1997	690	−	2.5 k	20	1.1 DL	−	200	−	>90%	[38]
	1998	940	−	100	7.5	2 DL	Liquid	100	−	98%	[39]
America LLNL	1995	150	25-30	6	14	1.25 DL	CCl₄	15	2.5	88%	[40]
Japan Osaka University	2003	362	−	1 k	29	1.2 DL	FC-75	90	−	75%	[41]
	2004	368	−	50	50	1.5 DL	FC-75 & FC-72	43	−	98%	[42]
	2012	766	−	100	−	−	FC-75 & FC-72	−	−	−	[43]
Germany Technische Universität Berlin	1997	104	−	100	90	−	Fiber	−	−	50%	[44]
Germany Technische Universität Berlin	2001	315	−	2 k	−	M²=2.6	Fiber	−	−	−	[30]
Australia EOS	2017	800	−	170	20	M²~3	FC-770	153	−	95.2%	[45]
China HIT	2008	−	106.6	20 min per shot	20	−	CCl₄	−	>30	~60%	[46]
China ZJU	2011	42	−	1 k	1.5	M²~2.3	Fiber	−	−	50%	[36]
China AOE	2017	1 k	−	200	6.6	1.7 DL	FC-770	220 W	−	98%	[3]
China AOE	2018	550	−	500	10	M²~2	FC-770	150 W	−	92%	[47]

Table 1. Applications of SBS-PCM in high power nanosecond lasers

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