Kenichi Nishikawa, Ioana Duţan, Christoph Köhn, Yosuke Mizuno
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引用次数: 1
Abstract
The Particle-In-Cell (PIC) method has been developed by Oscar Buneman, Charles Birdsall, Roger W. Hockney, and John Dawson in the 1950s and, with the advances of computing power, has been further developed for several fields such as astrophysical, magnetospheric as well as solar plasmas and recently also for atmospheric and laser-plasma physics. Currently more than 15 semi-public PIC codes are available which we discuss in this review. Its applications have grown extensively with increasing computing power available on high performance computing facilities around the world. These systems allow the study of various topics of astrophysical plasmas, such as magnetic reconnection, pulsars and black hole magnetosphere, non-relativistic and relativistic shocks, relativistic jets, and laser-plasma physics. We review a plethora of astrophysical phenomena such as relativistic jets, instabilities, magnetic reconnection, pulsars, as well as PIC simulations of laser-plasma physics (until 2021) emphasizing the physics involved in the simulations. Finally, we give an outlook of the future simulations of jets associated to neutron stars, black holes and their merging and discuss the future of PIC simulations in the light of petascale and exascale computing.
粒子-细胞(PIC)方法是由Oscar Buneman, Charles Birdsall, Roger W. Hockney和John Dawson在20世纪50年代发展起来的,随着计算能力的进步,在天体物理学、磁层和太阳等离子体等几个领域得到了进一步的发展,最近也用于大气和激光等离子体物理学。目前有超过15个半公开的PIC代码,我们在本文中讨论。随着世界各地高性能计算设备上可用的计算能力的增加,其应用程序得到了广泛的发展。这些系统允许研究天体物理等离子体的各种主题,如磁重联、脉冲星和黑洞磁层、非相对论性和相对论性冲击、相对论性喷流和激光等离子体物理。我们回顾了大量的天体物理现象,如相对论喷流、不稳定性、磁重联、脉冲星,以及激光等离子体物理的PIC模拟(直到2021年),强调了模拟中涉及的物理。最后,我们展望了中子星、黑洞及其合并相关喷流的未来模拟,并在千兆级和百亿亿级计算的基础上讨论了PIC模拟的未来。
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