Research Paper: Temperature Effect on the Hybrid Electron Spin- oscillation Entanglement in an Anisotropic Two- dimensional Quantum Dot

Research Paper: Temperature Effect on the Hybrid Electron Spin- oscillation Entanglement in an Anisotropic Two- dimensional Quantum Dot

Entanglement plays a fundamental role in the field of quantum computing and quantum communication. In real conditions, a physical system is never isolated and inevitably interacts with its surroundings. Temperature is one of these effects that mainly reduces entanglement. In real conditions, the sys...

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Bibliographic Details
Published in:Fīzīk-i kārburdī Īrān (Online) Vol. 14; no. 1; pp. 25 - 44
Main Authors: Fatemeh Amiri, Fatemeh Mohammadpour
Format: Journal Article
Language:Persian
Published: Alzahra University 01-03-2024
Subjects:
anisotropic quantum dot
hybrid entanglement
magnetic field
the rashba parameter
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Summary:Entanglement plays a fundamental role in the field of quantum computing and quantum communication. In real conditions, a physical system is never isolated and inevitably interacts with its surroundings. Temperature is one of these effects that mainly reduces entanglement. In real conditions, the system is at a non-zero temperature, which will lead to a mixed state. Therefore, in the present work, the combined thermal entanglement of electron spin-oscillation in an anisotropic two-dimensional quantum dot is investigated using the negativity criterion. The results show that the combined entanglements are strongly dependent on the changes of the controllable parameters, such as the Rashba parameter and the magnetic field. The thermal entanglement between the spin and the assembly of oscillators is zero at absolute zero temperature and reaches a maximum with increasing temperature and then tends to zero asymptotically. This temperature, at which the amount of entanglement reaches its maximum value, can be controlled by changing the magnetic field and the coupling of the Rashba parameter. These two factors also control the rate of reaching the asymptotic state. These results provide a way to control the degree of entanglement between electron degrees of freedom, which is a fundamental requirement of quantum information processing.
ISSN:2783-1043
2783-1051
DOI:10.22051/ijap.2023.44710.1345