First-Principles Theory for Schottky Barrier Physics

ORAL

Abstract

We develop a first-principles theory for Schottky barrier physics. The Poisson equation is solved self-consistently with the electrostatic charge density over the entire barrier using the density functional theory (DFT) electronic structure converged locally, allowing computation of a Schottky barrier entirely from DFT involving thousands of atomic layers in the semiconductor. The induced charge in the bulk consists of conduction and valence band charges from doping and band bending, as well as charge from the evanescent states in the gap of the semiconductor. The Schottky barrier height is determined when the induced charge density and the induced electrostatic potential reach self-consistency. A tests on the GaAs – graphene and Si/Al heterostructures are presented.

*This work was supported as part of the Center for Molecular Magnetic Quantum Materials (M2QM), an Energy Frontier Research Center funded by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences under Award DE-SC0019330.

Presenters

  • Dmitry Skachkov

    • University of Florida

Authors

  • Dmitry Skachkov

    • University of Florida

  • Xiaoguang Zhang

    • Department of Physics and the Quantum Theory Project, University of Florida
    • University of Florida
    • Department of Physics, Center for Molecular Magnetic Quantum Materials and Quantum Theory Project, University of Florida
    • Department of Physics, University of Florida
    • Department of Physics and the Quantum Theory Project, University of Florida, Gainesville, FL
    • Physics, University of Florida

  • Hai-Ping Cheng

    • University of Florida
    • Department of Physics, Center for Molecular Magnetic Quantum Materials and Quantum Theory Project, University of Florida
    • Department of Physics, University of Florida
    • Physics, University of Florida