Open AccessDerivation of New Quantum Hydrodynamic Equations Using Entropy Minimization
Author(s) -
Ansgar Jüngel,
Daniel Matthes,
Josipa Pina Milišić
Publication year - 2006
Publication title -
siam journal on applied mathematics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.954
H-Index - 99
eISSN - 1095-712X
pISSN - 0036-1399
DOI - 10.1137/050644823
Subject(s) - quantum hydrodynamics , planck constant , physics , quantum , boltzmann's entropy formula , boltzmann constant , vorticity , classical mechanics , boltzmann equation , quantum mechanics , mechanics , vortex
C† Abstract. New quantum hydrodynamic equations are derived from a Wigner-Boltzmann model, using the quantum entropy minimization method recently developed by Degond and Ringhofer. The model consists of conservation equations for the carrier, momentum, and energy densities. The derivation is based on a careful expansion of the quantum Maxwellian in powers of the Planck con- stant. In difference to the standard quantum hydrodynamic equations derived by Gardner, the new model includes vorticity terms and a dispersive term for the velocity. Numerical current-voltage char- acteristics of a one-dimensional resonant tunneling diode for both the new quantum hydrodynamic equations and Gardner's model are presented. The numerical results indicate that the dispersive velocity term regularizes the solution of the system.
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