English

Nested Dissection Solver for Transport in 3D Nano-Electronic Devices

Computational Physics 2017-02-20 v1

Abstract

The Hierarchical Schur Complement method (HSC), and the HSC-extension, have significantly accelerated the evaluation of the retarded Green's function, particularly the lesser Green's function, for two-dimensional nanoscale devices. In this work, the HSC-extension is applied to determine the solution of non-equilibrium Green's functions (NEGF) on three-dimensional nanoscale devices. The operation count for the HSC-extension is analyzed for a cuboid device. When a cubic device is discretized with N×N×NN \times N \times N grid points, the state-of-the-art Recursive Green Function (RGF) algorithm takes O(N7)\mathcal{O}(N^7) operations, whereas the HSC-extension only requires O(N6)\mathcal{O}(N^6) operations. %Realistic operation counts also depend on the system dimensions in xyzxyz-directions and the form of contact self-energy matrix. Operation counts and runtimes are also studied for three-dimensional nanoscale devices of practical interest: a graphene-boron\- nitride-graphene multilayer system, a silicon nanowire, and a DNA molecule. The numerical experiments indicate that the cost for the HSC-extension is proportional to the solution of one linear system (or one LU-factorization) and that the runtime speed-ups over RGF exceed three orders of magnitude when simulating realistic devices, such as a graphene-boron nitride-graphene multilayer system with 40,000 atoms.

Keywords

Cite

@article{arxiv.1702.05167,
  title  = {Nested Dissection Solver for Transport in 3D Nano-Electronic Devices},
  author = {Y. Zhao and U. Hetmaniuk and S. R. Patil and J. Qi and M. P. Anantram},
  journal= {arXiv preprint arXiv:1702.05167},
  year   = {2017}
}
R2 v1 2026-06-22T18:20:45.083Z