English

Connecting physics to systems with modular spin-circuits

Mesoscale and Nanoscale Physics 2024-11-07 v2 Emerging Technologies

Abstract

An emerging paradigm in modern electronics is that of CMOS + X\sf X requiring the integration of standard CMOS technology with novel materials and technologies denoted by X\sf X. In this context, a crucial challenge is to develop accurate circuit models for X\sf X that are compatible with standard models for CMOS-based circuits and systems. In this perspective, we present physics-based, experimentally benchmarked modular circuit models that can be used to evaluate a class of CMOS + X\sf X systems, where X\sf X denotes magnetic and spintronic materials and phenomena. This class of materials is particularly challenging because they go beyond conventional charge-based phenomena and involve the spin degree of freedom which involves non-trivial quantum effects. Starting from density matrices - the central quantity in quantum transport - using well-defined approximations, it is possible to obtain spin-circuits that generalize ordinary circuit theory to 4-component currents and voltages (1 for charge and 3 for spin). With step-by-step examples that progressively become more complex, we illustrate how the spin-circuit approach can be used to start from the physics of magnetism and spintronics to enable accurate system-level evaluations. We believe the core approach can be extended to include other quantum degrees of freedom like valley and pseudospins starting from corresponding density matrices.

Keywords

Cite

@article{arxiv.2404.19345,
  title  = {Connecting physics to systems with modular spin-circuits},
  author = {Kemal Selcuk and Saleh Bunaiyan and Nihal Sanjay Singh and Shehrin Sayed and Samiran Ganguly and Giovanni Finocchio and Supriyo Datta and Kerem Y. Camsari},
  journal= {arXiv preprint arXiv:2404.19345},
  year   = {2024}
}
R2 v1 2026-06-28T16:10:53.862Z