Compared study of Shannon, Tsallis and Gaussian entropy of bound magnetopolaron in nanostructures
M. Tiotsop, A. J. Fotue, H. B. Fotsin, L. C. Fai

TL;DR
This study compares Shannon, Tsallis, and Gaussian entropies in nanostructures, revealing their relative effectiveness in analyzing decoherence and information dynamics in quantum dots under various conditions.
Contribution
It provides a comparative analysis of three entropy measures in nanostructures, highlighting their different sensitivities and suitability for evaluating quantum decoherence and information exchange.
Findings
Gaussian entropy amplitude is greater than Tsallis and Shannon.
Gauss entropy is more suitable for evaluating average information.
Shannon entropy shows more significant amplitude with increasing delta length.
Abstract
Many methods have been experimented to study decoherence in nanostructures. Tsallis, Shannon and Gaussian entropy have been used to study decoherence separately; in this paper, we compared the results of the sus-mentioned entropies in nanostructures. The linear combination operator and the unitary transformation was used to derive the magnetopolaron spectrum that strongly interact with the LO phonons in the presence of electric field in the pseudo harmonic and delta quantum dot. Numerical results revealed for the quantum pseudo dot that: (i) The amplitude of Gauss entropy is greater than the amplitude of Tsallis entropy which inturn is greater than the amplitude of Shannon entropy. The Tsallis entropy is not more significant in nanostructure compared to Shannon and Gauss entropies, (ii) With an increase of the zero point, the dominance of the Gauss entropy on the Shannon entropy was…
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Taxonomy
TopicsQuantum and electron transport phenomena · Semiconductor Quantum Structures and Devices · stochastic dynamics and bifurcation
