Nonextensive statistics for a 2D electron gas in noncommutative spaces

TL;DR

This paper explores how noncommutative geometry and non-extensive Tsallis statistics influence the thermodynamics of a 2D electron gas under magnetic and electric fields, revealing novel regimes and electromagnetic properties.

Contribution

It introduces a framework combining noncommutative geometry with Tsallis statistics to analyze quantum thermodynamics of a 2D electron system, highlighting new thermodynamic behaviors.

Findings

Identification of new thermodynamic regimes due to noncommutativity and non-extensivity.

Derivation of generalized partition function, magnetization, and susceptibility in noncommutative space.

Observation of anomalous electromagnetic properties in the combined noncommutative and non-extensive context.

Abstract

This work investigates a quantum system described by a Hamiltonian operator in a two dimensional noncommutative space. The system consists of an electron subjected to a perpendicular magnetic field $\mathbf{B}$, coupled to a harmonic potential and an external electric field $\mathbf{E}$, within the context of non-extensive statistical thermodynamics. The noncommutative geometry introduces a fundamental minimal length that modifies the phase space structure. The thermodynamics of this quantum system is developed within the framework of Tsallis statistics through the derivation of $q$-generalized versions of the partition function, magnetization, and magnetic susceptibility, following the application of a generalized Hilhorst transformation adapted to non-commutative geometry. The combined effects of the non-extensivity parameter $q$ and the noncommutativity parameter $\theta$ are analyzed by considering the limit $q \rightarrow 1$, revealing new thermodynamic regimes and anomalous electromagnetic properties specific to quantum systems in non-commutative geometry.