Abstract
AbstractEntangled quantum particles, in which operating on one particle instantaneously influences the state of the entangled particle, are attractive options for carrying quantum information at the nanoscale. However, fully-describing entanglement in traditional time-dependent quantum transport simulation approaches requires significant computational effort, bordering on being prohibitive. Considering electrons, one approach to analyzing their entanglement is through modeling the Coulomb interaction via the Wigner formalism. In this work, we reduce the computational complexity of the time evolution of two interacting electrons by resorting to reasonable approximations. In particular, we replace the Wigner potential of the electron–electron interaction by a local electrostatic field, which is introduced through the spectral decomposition of the potential. It is demonstrated that for some particular configurations of an electron–electron system, the introduced approximations are feasible. Purity, identified as the maximal coherence for a quantum state, is also analyzed and its corresponding analysis demonstrates that the entanglement due to the Coulomb interaction is well accounted for by the introduced local approximation.
Funder
Austrian Science Fund
Christian Doppler Forschungsgesellschaft
TU Wien
Publisher
Springer Science and Business Media LLC
Subject
Electrical and Electronic Engineering,Modeling and Simulation,Atomic and Molecular Physics, and Optics,Electronic, Optical and Magnetic Materials
Reference32 articles.
1. Vasileska, D., Khan, H.R., Ahmed, S.S., Ringhofer, C., Heitzinger, C.: Quantum and Coulomb effects in nanodevices. Int. J. Nanosci. 4(3), 305–361 (2005)
2. Lapenta, G., Jiang, W.: Implicit temporal discretization and exact energy conservation for particle methods applied to the Poisson–Boltzmann equation. Plasma 1(2), 242–258 (2018)
3. Barraud, S., Dollfus, P., Galdin, S., Hesto, P.: Short-range and long-range Coulomb interactions for 3D Monte Carlo device simulation with discrete impurity distribution. Solid State Electron. 46, 1061–1067 (2002)
4. Vienna Schrödinger Poisson Solver (VSP): https://www.iue.tuwien.ac.at/software/vmc0/
5. Vienna Ab initio Simulation Package (VASP): https://www.vasp.at/
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