TY - JOUR
T1 - Implementation of a particle-in-cell method for the energy solver in 3D spherical geodynamic modeling
AU - Dong, Hao
AU - Cao, Zebin
AU - Liu, Lijun
AU - Li, Yanchong
AU - Li, Sanzhong
AU - Dai, Liming
AU - Li, Xinyu
N1 - This work was carried out at the National Supercomputer Center in Tianjin, and the calculations were performed on the TianHe new generation supercomputer. We are grateful to Ma Qingzhen and Li Taihe of the National Supercomputer Center in Tianjin for their patient assistance in providing the compilation environment. We thank the editor, Huajian Yao, for handling the manuscript and Mingming Li and another anonymous reviewer for their constructive comments. The research leading to these results has received funding from National Natural Science Foundation of China projects (Grant Nos. 92355302 and 42121005), Taishan Scholar projects (Grant No. tspd20210305), and others (Grant Nos. XDB0710000, L2324203, XK2023DXC001, LSKJ202204400, and ZR2021ZD09).
PY - 2024
Y1 - 2024
N2 - The thermal evolution of the Earth’s interior and its dynamic effects are the focus of Earth sciences. However, the commonly adopted grid-based temperature solver is usually prone to numerical oscillations, especially in the presence of sharp thermal gradients, such as when modeling subducting slabs and rising plumes. This phenomenon prohibits the correct representation of thermal evolution and may cause incorrect implications of geodynamic processes. After examining several approaches for removing these numerical oscillations, we show that the Lagrangian method provides an ideal way to solve this problem. In this study, we propose a particle-in-cell method as a strategy for improving the solution to the energy equation and demonstrate its effectiveness in both one-dimensional and three-dimensional thermal problems, as well as in a global spherical simulation with data assimilation. We have implemented this method in the open-source finite-element code CitcomS, which features a spherical coordinate system, distributed memory parallel computing, and data assimilation algorithms.
AB - The thermal evolution of the Earth’s interior and its dynamic effects are the focus of Earth sciences. However, the commonly adopted grid-based temperature solver is usually prone to numerical oscillations, especially in the presence of sharp thermal gradients, such as when modeling subducting slabs and rising plumes. This phenomenon prohibits the correct representation of thermal evolution and may cause incorrect implications of geodynamic processes. After examining several approaches for removing these numerical oscillations, we show that the Lagrangian method provides an ideal way to solve this problem. In this study, we propose a particle-in-cell method as a strategy for improving the solution to the energy equation and demonstrate its effectiveness in both one-dimensional and three-dimensional thermal problems, as well as in a global spherical simulation with data assimilation. We have implemented this method in the open-source finite-element code CitcomS, which features a spherical coordinate system, distributed memory parallel computing, and data assimilation algorithms.
KW - energy solver
KW - finite element method
KW - numerical oscillation
KW - overshooting and undershooting
KW - particle-in-cell method
KW - three-dimensional spherical geodynamic modeling
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U2 - 10.26464/epp2024021
DO - 10.26464/epp2024021
M3 - Article
AN - SCOPUS:85193957849
SN - 2096-3955
VL - 8
SP - 549
EP - 563
JO - Earth and Planetary Physics
JF - Earth and Planetary Physics
IS - 3
ER -