Related papers: Thermal quantum correlations of a single electron in a double quantum dot with transverse magnetic field

Thermal quantum correlations of a single electron in a double quantum dot with transverse magnetic field

URL: http://arxiv.org/abs/2412.19046v1
Date: Thu, 26 Dec 2024 03:43:36 GMT
Title: Thermal quantum correlations of a single electron in a double quantum dot with transverse magnetic field
Authors: Vinicius Leitão, Onofre Rojas, Moises Rojas,
Abstract summary: We investigate the thermal quantum correlations in a semiconductor double quantum dot system. We highlight the roles of thermal entanglement and correlated coherence in generating quantum correlations. This suggests that quantum algorithms based solely on correlated coherence might be more resilient than those relying on entanglement.
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Abstract: In this paper, we investigate the thermal quantum correlations in a semiconductor double quantum dot system. The device comprises a single electron in a double quantum dot subjected to a longitudinal magnetic field and a transverse magnetic field gradient. The thermal entanglement of the single electron is driven by the charge and spin qubits. Utilizing the density matrix formalism, we derive analytical expressions for thermal concurrence and correlated coherence. The main goal of this work is to provide a good understanding of the effects of temperature and various parameters on quantum coherence. Additionally, our findings indicate that the transverse magnetic field can be employed to adjust the thermal entanglement and quantum coherence of the system. We also highlight the roles of thermal entanglement and correlated coherence in generating quantum correlations, noting that thermal correlated coherence is consistently more robust than thermal entanglement. This suggests that quantum algorithms based solely on correlated coherence might be more resilient than those relying on entanglement.

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