What question did this study set out to answer?

The study aims to investigate how supersymmetry influences statistical and complexity measures in quantum systems.

March 18, 2026Open Access

Statistical Measures and Complexity of Supersymmetric Polynomials in Quantum Mechanics

Key Points

The study aims to investigate how supersymmetry influences statistical and complexity measures in quantum systems.
Analyzed information-theoretic measures using Dunkl-supersymmetric harmonic oscillator functions.
Calculated Shannon entropy in both asymptotic and closed analytic forms.
Evaluated spreading measures, including Heller, Rényi, and Fisher lengths.
Supersymmetry does not impact the leading scaling of Shannon entropy.
Spreading measures indicate enhanced localization of SUSY eigenstates compared to standard harmonic oscillators.
LMC and Fisher–Shannon complexities are found to be higher in the supersymmetric context.

Abstract

We study information-theoretic and complexity measures for the Dunkl-supersymmetric harmonic oscillator to identify the effect of supersymmetry on these quantities. Using the Rakhmanov probability density of the Dunkl-SUSY functions, we analyze the Shannon entropy, spreading measures (Heller, Rényi, and Fisher lengths), and several statistical and dynamical complexities. The Shannon entropy is obtained both asymptotically and in closed analytic form, showing that supersymmetry does not affect the leading large-n scaling. In contrast, spreading measures reveal enhanced localization of the SUSY eigenstates relative to the standard harmonic oscillator. Finally, we find that LMC and Fisher–Shannon complexities are higher in the supersymmetric case.

Statistical Measures and Complexity of Supersymmetric Polynomials in Quantum Mechanics

Key Points

Abstract

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