A benchmark study of the Signed-particle Monte Carlo algorithm for the Wigner equation

Muscato, Orazio

doi:10.1515/caim-2017-0012

Cited by 11 publications

(15 citation statements)

References 32 publications

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“…We leave more complex scenarios for future work. In addition to these two models we have also reproduced results previously reported in the literature of scattering from a Gaussian barrier 15,20 . Please see Appendix B for these results and discussion.…”

Section: Resultssupporting

confidence: 82%

Solving the Wigner Equation with Signed Particles Monte Carlo for Chemically Relevant Potentials

Wang¹,

Simine

2021

Preprint

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Section: Resultssupporting

confidence: 82%

Solving the Wigner Equation with Signed Particles Monte Carlo for Chemically Relevant Potentials

Wang¹,

Simine

2021

Preprint

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“…Further developments could include the effects of crystal heating and quantum effects in the mobility models. Although the subject is still in an early stage, attempts in this direction can be found in [10,11] regarding the thermal influence on the electric performance, and in [12][13][14][15] regarding the inclusion of quantum corrections.…”

Section: Discussionmentioning

confidence: 99%

Improved mobility models for charge transport in graphene

Nastasi

Romano

2019

Communications in Applied and Industrial Mathematics

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Charge transport in graphene is crucial for the design of a new generation of nanoscale electron devices. A reasonable model is represented by the semiclassical Boltzmann equations for electrons in the valence and conduction bands. As shown by Romano et al. (J. Comput. Phys., 2015), the discontinuous Galerkin methods are a viable way to tackle the problem of the numerical integration of these equations, even if efficient DSMC with a proper inclusion of the Pauli principle have been also devised. One of the advantages of the solutions obtained with deterministic approach is of course the absence of statistical noise. This fact is crucial for an accurate estimation of the low field mobility as proved by Majorana et al. (J. Math. Industry, 2016) in the case of a unipolar charge transport in a suspended graphene sheet under a constant electric field. The mobility expressions are essential for the drift-diffusion equations which constitute the most adopted models for charge transport in CAD. Here the analysis by Majorana et al. (J. Math. Industry, 2016) is improved in two ways: by including the charge transport both in the valence and conduction bands; by taking into account the presence of an oxide as substrate for the graphene sheet. New models of mobility are obtained and, in particular, relevant improvements of the low field mobility are achieved.

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“…The kernel (13) without a majorant (or, withV W = |V W |) was considered in [17]. The kernel (13) with a majorant was used in [10], [7] in the context of a class of time splitting algorithms (transport and creation steps were separated).…”

Section: Algorithmmentioning

confidence: 99%

A stochastic algorithm without time discretization error for the Wigner equation

Muscato¹,

Wagner²

2019

Kinetic &Amp; Related Models

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Stochastic particle methods for the numerical treatment of the Wigner equation are considered. The approximation properties of these methods depend on several numerical parameters. Such parameters are the number of particles, a time step (if transport and other processes are treated separately) and the grid size (used for the discretization of the position and the wave-vector). A stochastic algorithm without time discretization error is introduced. Its derivation is based on the theory of piecewise deterministic Markov processes. Numerical experiments are performed in a one-dimensional test case. Approximation properties with respect to the grid size and the number of particles are studied. Convergence of a time-splitting scheme to the no-splitting algorithm is demonstrated. The no-splitting algorithm is shown to be more efficient in terms of computational effort.

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A benchmark study of the Signed-particle Monte Carlo algorithm for the Wigner equation

Cited by 11 publications

References 32 publications

Solving the Wigner Equation with Signed Particles Monte Carlo for Chemically Relevant Potentials

Solving the Wigner Equation with Signed Particles Monte Carlo for Chemically Relevant Potentials

Improved mobility models for charge transport in graphene

A stochastic algorithm without time discretization error for the Wigner equation

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