Diagnosing inertial confinement fusion ignition

IF 3.5 1区物理与天体物理 Q1 PHYSICS, FLUIDS & PLASMAS Nuclear Fusion Pub Date : 2024-09-04 DOI:10.1088/1741-4326/ad703b

A.S. Moore, L. Divol, B. Bachmann, R. Bionta, D. Bradley, D.T. Casey, P. Celliers, H. Chen, A. Do, E. Dewald, M. Eckart, D. Fittinghoff, J. Frenje, M. Gatu-Johnson, H. Geppert-Kleinrath, V. Geppert-Kleinrath, G. Grim, K. Hahn, M. Hohenberger, J. Holder, O. Hurricane, N. Izumi, S. Kerr, S.F. Khan, J.D. Kilkenny, Y. Kim, B. Kozioziemski, N. Lemos, A.G. MacPhee, P. Michel, M. Millot, K.D. Meaney, S. Nagel, A. Pak, J.E. Ralph, J.S. Ross, M.S. Rubery, D.J. Schlossberg, V. Smalyuk, G. Swadling, R. Tommasini, C. Trosseille, A.B. Zylstra, A. Mackinnon, J.D. Moody, O.L. Landen, R. Town

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Abstract

Fusion ignition by inertial confinement requires compression and heating of the fusion fuel to temperatures in excess of 5 keV and densities exceeding hundreds of g/cc. In August 2021, this scientific milestone was surpassed at the National Ignition Facility (NIF), when the Lawson criterion for ignition was exceeded generating 1.37MJ of fusion energy (Abu-Shawareb et al 2022 Phys. Rev. Lett. 129 075001), and then in December 2022 target gain >1 was realized with the production of 3.1MJ of fusion energy from a target driven by 2.0MJ of laser energy (Abu-Shawareb et al 2024 Phys. Rev. Lett. 132 065102). At the NIF, inertial confinement fusion research primarily uses a laser indirect drive in which the fusion capsule is surrounded by a high-Z enclosure (‘hohlraum’) used to convert the directed laser energy into a symmetric x-ray drive on the capsule. Precise measurements of the plasma conditions, x-rays, γ-rays and neutrons produced are key to understanding the pathway to higher performance. This paper discusses the diagnostics and measurement techniques developed to understand these experiments, focusing on three main topics: (1) key diagnostic developments for achieving igniting plasmas, (2) novel signatures related to thermonuclear burn and (3) advances to diagnostic capabilities in the igniting regime with a perspective toward developments for intertial fusion energy.

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诊断惯性约束聚变点火

利用惯性约束点燃核聚变需要将核聚变燃料压缩和加热到超过 5 keV 的温度和超过数百 g/cc 的密度。2021 年 8 月，国家点火装置（NIF）超越了这一科学里程碑，点火能量超过了劳森标准，产生了 137 万焦耳的聚变能（Abu-Shawareb 等人，2022 年物理评论快报 129 075001），随后在 2022 年 12 月实现了目标增益>1，由 200 万焦耳激光能量驱动的目标产生了 310 万焦耳的聚变能（Abu-Shawareb 等人，2024 年物理评论快报 132 065102）。在 NIF，惯性约束聚变研究主要使用激光间接驱动，其中聚变囊周围有一个高 Z 围栏（"hohlraum"），用于将定向激光能量转换成囊上的对称 X 射线驱动。对等离子体条件、产生的 X 射线、γ 射线和中子进行精确测量是了解实现更高性能的关键。本文讨论了为了解这些实验而开发的诊断和测量技术，重点关注三个主要议题：(1) 实现点燃等离子体的关键诊断发展，(2) 与热核燃料有关的新特征，以及 (3) 点燃系统诊断能力的进展，并着眼于间歇聚变能的发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nuclear Fusion 物理-物理：核物理

CiteScore

6.30

自引率

39.40%

发文量

411

审稿时长

2.6 months

期刊介绍： Nuclear Fusion publishes articles making significant advances to the field of controlled thermonuclear fusion. The journal scope includes: -the production, heating and confinement of high temperature plasmas; -the physical properties of such plasmas; -the experimental or theoretical methods of exploring or explaining them; -fusion reactor physics; -reactor concepts; and -fusion technologies. The journal has a dedicated Associate Editor for inertial confinement fusion.