Asymptotic-Preserving Exponential Methods for the Quantum Boltzmann Equation with High-Order Accuracy

Jingwei Hu; Qin Li; Lorenzo Pareschi

doi:10.1007/s10915-014-9869-2

Asymptotic-Preserving Exponential Methods for the Quantum Boltzmann Equation with High-Order Accuracy

Jingwei Hu, Qin Li, Lorenzo Pareschi

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

In this paper we develop high order asymptotic preserving methods for the spatially inhomogeneous quantum Boltzmann equation. We follow the work in Li and Pareschi (J Comput Phys 259:402–420, 2014) where asymptotic preserving exponential Runge–Kutta methods for the classical inhomogeneous Boltzmann equation were constructed. A major difficulty here is related to the non Gaussian steady states characterizing the quantum kinetic behavior. We show that the proposed schemes achieve high-order accuracy uniformly in time for all Planck constants ranging from classical regime to quantum regime, and all Knudsen number ranging from kinetic regime to fluid regime. Computational results are presented for both Bose gas and Fermi gas.

Original language	English
Pages (from-to)	555-574
Number of pages	20
Journal	Journal of Scientific Computing
Volume	62
Issue number	2
DOIs	https://doi.org/10.1007/s10915-014-9869-2
State	Published - Feb 2014
Externally published	Yes

Keywords

Asymptotic preserving methods
Exponential Runge–Kutta schemes
Quantum Boltzmann equation

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10.1007/s10915-014-9869-2

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title = "Asymptotic-Preserving Exponential Methods for the Quantum Boltzmann Equation with High-Order Accuracy",

abstract = "In this paper we develop high order asymptotic preserving methods for the spatially inhomogeneous quantum Boltzmann equation. We follow the work in Li and Pareschi (J Comput Phys 259:402–420, 2014) where asymptotic preserving exponential Runge–Kutta methods for the classical inhomogeneous Boltzmann equation were constructed. A major difficulty here is related to the non Gaussian steady states characterizing the quantum kinetic behavior. We show that the proposed schemes achieve high-order accuracy uniformly in time for all Planck constants ranging from classical regime to quantum regime, and all Knudsen number ranging from kinetic regime to fluid regime. Computational results are presented for both Bose gas and Fermi gas.",

keywords = "Asymptotic preserving methods, Exponential Runge–Kutta schemes, Quantum Boltzmann equation",

author = "Jingwei Hu and Qin Li and Lorenzo Pareschi",

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AU - Hu, Jingwei

AU - Li, Qin

AU - Pareschi, Lorenzo

PY - 2014/2

Y1 - 2014/2

N2 - In this paper we develop high order asymptotic preserving methods for the spatially inhomogeneous quantum Boltzmann equation. We follow the work in Li and Pareschi (J Comput Phys 259:402–420, 2014) where asymptotic preserving exponential Runge–Kutta methods for the classical inhomogeneous Boltzmann equation were constructed. A major difficulty here is related to the non Gaussian steady states characterizing the quantum kinetic behavior. We show that the proposed schemes achieve high-order accuracy uniformly in time for all Planck constants ranging from classical regime to quantum regime, and all Knudsen number ranging from kinetic regime to fluid regime. Computational results are presented for both Bose gas and Fermi gas.

AB - In this paper we develop high order asymptotic preserving methods for the spatially inhomogeneous quantum Boltzmann equation. We follow the work in Li and Pareschi (J Comput Phys 259:402–420, 2014) where asymptotic preserving exponential Runge–Kutta methods for the classical inhomogeneous Boltzmann equation were constructed. A major difficulty here is related to the non Gaussian steady states characterizing the quantum kinetic behavior. We show that the proposed schemes achieve high-order accuracy uniformly in time for all Planck constants ranging from classical regime to quantum regime, and all Knudsen number ranging from kinetic regime to fluid regime. Computational results are presented for both Bose gas and Fermi gas.

KW - Asymptotic preserving methods

KW - Exponential Runge–Kutta schemes

KW - Quantum Boltzmann equation

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IS - 2

ER -

Asymptotic-Preserving Exponential Methods for the Quantum Boltzmann Equation with High-Order Accuracy

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