Integrated Multiscale Framework for Advanced Magnetic Simulations.

Precise control of the magnetic phases of matter has revolutionized technology in recent decades. The discovery of novel magnetic materials has radically raised the expectations towards ultra-fast yet low-power-consumption spintronic applications. Especially, numerical simulations of magnetic materials have played an indisputable role in predicting and understanding non-trivial magnetic states for applications. However, although different numerical approaches are readily verified to accurately represent the magnetic behavior in different scenarios, a complete description of magnetic phases often requires a laborious connection between numerous simulation packages which operate at different time and length scales. In this project, we collaborate with key specialists to develop an open-source integrated multiscale framework for state-of-the-art magnetic simulations, from first principles to micromagnetic regimes. This will require advancing a precise interconnection between different (pre-existing) numerical approaches to accurately describe magnetic phases at different time and length scales, bringing magnetic simulations to an unprecedented and extremely versatile level.

Keywords:SPINTRONICS, NUMERICAL SIMULATIONS, MAGNETIC MATERIALS

Disciplines:Magnetism and superconductivity, Surfaces, interfaces, 2D materials