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当前位置：物理科学与技术研究 > 2025年 5卷 (1)期

Open Access Article

Physical Science and Technical Research. 2025; 5: (1) ; 52-61 ; DOI: 10.12208/j.pstr.20250008.

Physics idea, mathematical language, and application prospective of self-coagulation process
自凝聚过程的物理思想、数学语言和应用前景

作者： 赵书霞¹ *, 唐瑞基¹, 田宇²

1 大连理工大学物理学院辽宁大连

2 大连科技学院工训中心辽宁大连

*通讯作者：赵书霞,单位：大连理工大学物理学院辽宁大连；

发布时间: 2025-03-15 总浏览量: 82

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摘要

本文基于Ar/SF₆感性耦合放电流体力学模拟随时间的演化过程，演绎出该等离子体源的放电结构层次，重点讨论了居于放电结构核心的自凝聚动力学过程，揭示了它的物理思想、数学语言，以及在核聚变领域的应用前景。其中对其应用前景的预测主要依赖于自凝聚过程的一个显著特征，即体积越大，物质自凝聚形成的密度越高。最后比较了自凝聚过程和太阳核聚变的内在驱动力大小，即静电力和万有引力，并由此粗浅地估计了人造的、自由核聚变可能发生的尺度范围。

关键词： 自凝聚；Ar/SF₆感性耦合等离子体；流体模拟；放电结构层次

Abstract

The complex discharge structure hierarchy of Ar/SF₆ inductively coupled discharge is revealed based on the temporal evolution of fluid simulation of this source. Among this, the self-coagulation dynamics lied in the core of discharge structure hierarchy is emphasized and the physics idea, the mathematical language, and the potential application of self-coagulation in the fusion field are described. Herein, the prediction of self-coagulation application in fusion is based on one of its key characteristics, i.e., the coagulated mass density is higher in a larger volume.

Key words： Self-coagulation; Ar/SF₆ inductively coupled plasma; Fluid simulation; Discharge structure hierarchy

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引用本文

赵书霞, 唐瑞基, 田宇, 自凝聚过程的物理思想、数学语言和应用前景[J]. 物理科学与技术研究, 2025; 5: (1) : 52-61.

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