直接优化恒星器反应器中的新古典离子传输

IF 3.5 1区物理与天体物理 Q1 PHYSICS, FLUIDS & PLASMAS

Nuclear Fusion Pub Date : 2024-09-09 DOI:10.1088/1741-4326/ad75a6

B.F. Lee, S.A. Lazerson, H.M. Smith, C.D. Beidler and N.A. Pablant

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引用次数: 0

摘要

我们直接优化了恒星器的新古典离子传输，同时将新古典电子传输保持在中等水平，从而创造了一种有利于杂质驱逐并保持良好离子约束的环境。传统的新古典恒星器优化主要集中在最大限度地减小，该几何因子表征了粒子在该系统中的径向传输量。在预期的反应堆相关条件下，堆芯电子将处于态，堆芯燃料离子将处于态。因此，传统的优化方法最大限度地减少了电子传输，而依赖于为限制离子而形成的径向电场（Er）。这通常会导致向内的 Er，从而将高 Z 杂质带入堆芯，这可能会给未来的反应堆带来麻烦。在这项工作中，我们提高了热传输系数的比值，之前的研究表明这可以产生向外的 Er。这种效应对杂质排出非常有利。我们在反应堆相关条件下获得了自洽的密度、温度和 Er 曲线，并优化了平衡。这种平衡有望显著改善杂质迁移特性。

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Direct optimization of neoclassical ion transport in stellarator reactors

We directly optimize stellarator neoclassical ion transport while holding neoclassical electron transport at a moderate level, creating a scenario favorable for impurity expulsion and retaining good ion confinement. Traditional neoclassical stellarator optimization has focused on minimizing , the geometric factor that characterizes the amount of radial transport due to particles in the regime. Under expected reactor-relevant conditions, core electrons will be in the regime and core fuel ions will be in the regime. Traditional optimizations thus minimize electron transport and rely on the radial electric field (Er) that develops to confine the ions. This often results in an inward-pointing Er that drives high-Z impurities into the core, which may be troublesome in future reactors. In this work, we increase the ratio of the thermal transport coefficients , which previous research has shown can create an outward-pointing Er. This effect is very beneficial for impurity expulsion. We obtain self-consistent density, temperature, and Er profiles at reactor-relevant conditions for an optimized equilibrium. This equilibrium is expected to enjoy significantly improved impurity transport properties.

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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.