Driver at 10 MJ and 1 shot/30 min for inertial confinement fusion at high gain: Efficient, compact, low-cost, low laser–plasma instabilities, beam color selectable from 2ω/3ω/4ω, applicable to multiple laser fusion schemes

Zhan Sui; Ke Lan

doi:10.1063/5.0216435

Matter and Radiation at Extremes, Volume. 9, Issue 4, 043002(2024)

Driver at 10 MJ and 1 shot/30 min for inertial confinement fusion at high gain: Efficient, compact, low-cost, low laser–plasma instabilities, beam color selectable from 2ω/3ω/4ω, applicable to multiple laser fusion schemes

Zhan Sui^1、a) and Ke Lan²

Author Affiliations

¹Shanghai Institute of Laser Plasma, China Academy of Engineering Physics, Shanghai 201800, China

²Institute of Applied Physics and Computational Mathematics, Beijing 100094, China

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References(17)

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[2] for more information about the new fusion yield record of 5.2 MJ on the NIF.

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[4] K.Lan. Dream fusion in octahedral spherical hohlraum. Matter Radiat. Extremes, 7, 055701(2022).

[5] 2015 review of the inertial confinement fusion and high energy density science portfolio: Volume I. Lasers Indirect Drive Input to NNSA 2020 Report, LLNL-TR-810573, DOE/NA-0040(2016).

[6] J. M.Auerbach, C. A.Haynam, P. J.Wegner et al. National Ignition Facility laser performance status. Appl. Opt, 46, 3276-3203(2007).

[7] K. R.Maneset?al.. Damage mechanisms avoided or managed for NIF large optics. Fusion Sci. Technol., 69, 146-249(2016).

[8] K.Lan, K.Lan, K.Lanet?al.. Novel spherical hohlraum with cylindrical laser entrance holes and shields. Phys. Plasmas, 21, 090704(2014).

[9] Y.Guoet?al.. Suppression of stimulated Raman scattering by angularly incoherent light, towards a laser system of incoherence in all dimensions of time, space, and angle. Matter Radiat. Extremes, 8, 035902(2023).

[10] M. L.Spaeth et al. National Ignition Facility laser system performance. Fusion Sci. Technol, 69, 366-394(2016).

[11] E. M.Campbell, S.Craxton, W. Y.Wang. A new beam configuration to support both spherical hohlraums and symmetric direct drive.

[12] M.Marangola. Optimization of direct drive designs for a proposed dual direct/indirect drive laser.

[13] D. A.Callanhan, S. W.Haan, J. D.Lindl et al. Point design targets, specifications, and requirements for the 2010 ignition campaign on the National Ignition Facility. Phys. Plasmas, 18, 051001(2011).

[14] Y.-H.Chen, K.Lan, G.Ren et al. Octahedral spherical Hohlraum for Rev. 6 NIF beryllium capsule. Phys. Plasmas, 25, 102701(2018).

[15] K.Lan, X.Qiao. Novel target designs to mitigate hydrodynamic instabilities growth in inertial confinement fusion. Phys. Rev. Lett, 126, 185001(2021).

[16] K.Lan, P.Song. Foam Au driven by 4ω–2ω ignition laser pulse for inertial confinement fusion. Phys. Plasmas, 24, 052707(2017).

[17] E. M.Campbell, Y.Chen, K.Lan, W.Zheng. High coupling efficiency of foam spherical hohlraum driven by 2ω laser light. Phys. Plasmas, 25, 022702(2018).

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Zhan Sui, Ke Lan. Driver at 10 MJ and 1 shot/30 min for inertial confinement fusion at high gain: Efficient, compact, low-cost, low laser–plasma instabilities, beam color selectable from 2ω/3ω/4ω, applicable to multiple laser fusion schemes[J]. Matter and Radiation at Extremes, 2024, 9(4): 043002

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Paper Information

Category:

Received: Apr. 29, 2024

Accepted: May. 22, 2024

Published Online: Aug. 13, 2024

The Author Email: Zhan Sui (lqling@vip.163.com)

DOI:10.1063/5.0216435

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology