Complex Quantum Hydrodynamics in Momentum Space with Broken Time-Reversal Symmetry

Shortly after Schrödinger’s wave mechanics in terms of complex wave functions was published, Madelung formulated this theory in terms of two real hydrodynamic-like equations. This version is also the formal basis of Bohmian mechanics, albeit with a different ontological interpretation. A point of cr...

Full description

Saved in:
Bibliographic Details
Published in:Symmetry (Basel) 2023-07, Vol.15 (7), p.1347
Main Authors: Schuch, Dieter, Bonilla-Licea, Moise
Format: Article
Language:English
Subjects:
broken time-reversal symmetry
complex quantum hydrodynamics
Dissipation
Flow control
Fluid dynamics
Fluid mechanics
Friction
Hamiltonian functions
Hydrodynamics
Mathematical analysis
Momentum
momentum space
Ontology
Open systems
Quantum mechanics
Quantum physics
Quantum theory
Symmetry
Variables
Velocity
Wave functions
Wave mechanics
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Shortly after Schrödinger’s wave mechanics in terms of complex wave functions was published, Madelung formulated this theory in terms of two real hydrodynamic-like equations. This version is also the formal basis of Bohmian mechanics, albeit with a different ontological interpretation. A point of criticism raised by Pauli against Bohmian mechanics is its missing symmetry between position and momentum that is present in classical phase space as well as in the quantum mechanical position and momentum representations. Both Madelung’s quantum hydrodynamics formulation and Bohmian mechanics are usually expressed only in position space. Recently, with the use of complex quantities, we were able to provide a hydrodynamic formulation also in momentum space. In this paper, we extend this formalism to include dissipative systems with broken time-reversal symmetry. In classical Hamiltonian mechanics and conventional quantum mechanics, closed systems with reversible time-evolution are usually considered. Extending the discussion to include open systems with dissipation, another form of symmetry is broken, that under time-reversal. There are different ways of describing such systems; for instance, Langevin and Fokker–Planck-type equations are commonly used in classical physics. We now investigate how these aspects can be incorporated into our complex hydrodynamic description and what modifications occur in the corresponding equations, not only in position, but particularly in momentum space.
ISSN:2073-8994
2073-8994
DOI:10.3390/sym15071347