Review of Analytical Modeling and Computational Solutions for Thermo-electrostatics Effects of Slender Bodies

Analysis method and computational solutions for thermo-and electrostatics effects of slender bodies often using multi-scale modeling, molecular dynamic simulation and data visualization technique. In the present work, we conduct a review of applying analytical methods such as BEM and FEM and molecular dynamics and computational methodologies to model the thermal and electrostatics effects on the slender body. A molecular dynamics simulation is employed to obtain logical relationships at nano-level in the modeling and simulation. The simulation is conducted on a cloud-based computing system in a heterogeneous computational environment. It helps overcome the technical challenges cause by multiple-scale physics model, and both computational and data intensive simulations.

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