Entanglement, separability and correlation topology of interacting qubits

• URL: http://arxiv.org/abs/2412.10480v1
• Date: Fri, 13 Dec 2024 08:39:05 GMT
• Title: Entanglement, separability and correlation topology of interacting qubits
• Authors: Basudev Nag Chowdhury,
• Abstract summary: It has been shown that the evolved combined state of such qubits may be either a separable or an entangled state depending on the nature and parameters of the potential. A novel method of qubit phase measurement by copying it to other qubits is explored.
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• Abstract: The present work investigates the possible correlation topologies of two interacting qubits in the parameter space of their interacting potential. It has been shown that the evolved combined state of such qubits may be either a separable or an entangled state depending on the nature and parameters of the potential, although it is impossible to travel from one maximally entangled state to another in the topological space by continuously varying such parameters without crossing an intermediate separable state, and vice-versa. The possible theoretical constructs of such interaction potentials required for rotating a qubit state through the two angular directions on its Bloch sphere are illustrated, and consequently a novel method of qubit phase measurement by copying it to other qubits is explored. Furthermore, the possibility of entanglement generation between two qubits by initially violating energy conservation while conserving energy at the end is described, and the non-local manipulation of the degree of entanglement is illustrated. Such investigations on the separability/entanglement between interacting qubits suggest that further extensive study on the fundamental quantum paradoxes as well as the basic decoherence models are also necessary for advancing the field of quantum technology in general.

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