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Spectral maximum entropy hydrodynamics of fermionic radiation: a three-moment system for one-dimensional flows

Authors :
Wieslaw Larecki
Zbigniew Banach
Source :
Nonlinearity. 26:1667-1701
Publication Year :
2013
Publisher :
IOP Publishing, 2013.

Abstract

The spectral formulation of the nine-moment radiation hydrodynamics resulting from using the Boltzmann entropy maximization procedure is considered. The analysis is restricted to the one-dimensional flows of a gas of massless fermions. The objective of the paper is to demonstrate that, for such flows, the spectral nine-moment maximum entropy hydrodynamics of fermionic radiation is not a purely formal theory. We first determine the domains of admissible values of the spectral moments and of the Lagrange multipliers corresponding to them. We then prove the existence of a solution to the constrained entropy optimization problem. Due to the strict concavity of the entropy functional defined on the space of distribution functions, there exists a one-to-one correspondence between the Lagrange multipliers and the moments. The maximum entropy closure of moment equations results in the symmetric conservative system of first-order partial differential equations for the Lagrange multipliers. However, this system can be transformed into the equivalent system of conservation equations for the moments. These two systems are consistent with the additional conservation equation interpreted as the balance of entropy. Exploiting the above facts, we arrive at the differential relations satisfied by the entropy function and the additional function required to close the system of moment equations. We refer to this additional function as the moment closure function. In general, the moment closure and entropy–entropy flux functions cannot be explicitly calculated in terms of the moments determining the state of a gas. Therefore, we develop a perturbation method of calculating these functions. Some additional analytical (and also numerical) results are obtained, assuming that the maximum entropy distribution function tends to the Maxwell–Boltzmann limit.

Details

ISSN :
13616544 and 09517715
Volume :
26
Database :
OpenAIRE
Journal :
Nonlinearity
Accession number :
edsair.doi...........2f59405ec4e1346c8f4d10624947917e
Full Text :
https://doi.org/10.1088/0951-7715/26/6/1667