PCell:用于可视化对流浆细胞的2D程序

R. Carboni, F. Frutos-Alfaro
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引用次数: 3

摘要

大多数天体和宇宙区域的磁场强度是已知的;它们的范围从星系间等离子体的10/sup -9/ G到中子星表面的10/sup 12/ G。大多数研究人员用来理解这种发电机机制的方法是考虑具有静止运动的宇宙等离子体,这导致了一个感应问题,其目标是找到作为感应方程解的静止状态。这种方程很容易用计算机解出来。通过选择对流速度场,我们可以模拟对流细胞,从而帮助我们理解光球层、色球层、太阳对流区和实验室等离子体的行为。我们也可以用这种方式来研究不太清楚的重连现象。PCell程序有助于可视化磁场在不同对流等离子体中的演变。我们用C语言编写程序(部分程序从Fortran语言翻译成C语言);它运行在Linux或Unix上。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
PCell: a 2D program for visualizing convective plasma cells
The magnetic field intensity of most celestial bodies and regions of the universe are known; they range from 10/sup -9/ G in the intergalactic plasma to 10/sup 12/ G at the surface of neutron stars. The approach most researchers use to understand this dynamo mechanism is to consider a cosmic plasma with a stationary motion, which leads to an induction problem where the goal is to find stationary states as solutions of the induction equation. This kind of equation is easily solved via a computer. By choosing convective velocity fields, we can simulate convection cells, which in turn help us understand the behavior of the photosphere, the chromosphere, the Sun's convective zone, and laboratory plasmas. We can also investigate the not-well-understood phenomena of reconnection in this way. The PCell program helps visualize the magnetic field's evolution in different convective plasmas. We wrote the program in C (part of the program was translated from Fortran to C); it runs on Linux or Unix.
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