Boris computational spintronics—High performance multi-mesh magnetic and spin transport modeling software

Lepadatu, Serban orcid iconORCID: 0000-0001-6221-9727 (2020) Boris computational spintronics—High performance multi-mesh magnetic and spin transport modeling software. Journal of Applied Physics, 128 (24). p. 243902. ISSN 0021-8979

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Official URL: https://doi.org/10.1063/5.0024382

Abstract

This work discusses the design and testing of a new computational spintronics research software. Boris is a comprehensive multi-physics open-source software, combining micromagnetics modeling capabilities with drift-diffusion spin transport modeling and a heat flow solver in multi-material structures. A multi-mesh paradigm is employed, allowing modeling of complex multi-layered structures with independent discretization and arbitrary relative positioning between different computational meshes. Implemented micromagnetics models include not only ferromagnetic materials modeling, but also two-sublattice models, allowing simulations of antiferromagnetic and ferrimagnetic materials, fully integrated into the multi-mesh and multi-material design approach. High computational performance is an important design consideration in Boris, and all computational routines can be executed on graphical processing units (GPUs), in addition to central processing units. In particular, a modified 3D convolution algorithm is used to compute the demagnetizing field on the GPU, termed pipelined convolution, and benchmark comparisons with existing GPU-accelerated software Mumax3 have shown performance improvements up to twice faster.


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