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This research explores how non-Hermiticity influences thermal entanglement and phase transitions in a two-qubit system.

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April 10, 2026

Non-Hermiticity induced thermal entanglement phase transition

Key Points

This research explores how non-Hermiticity influences thermal entanglement and phase transitions in a two-qubit system.
Theoretical analysis of a two-qubit effective non-Hermitian system
Characterization of asymmetric Heisenberg XY interactions
Assessment of entanglement at thermal equilibrium
Investigation of the non-Hermiticity parameter's impact on entanglement
Maximal entanglement achieved at T→0 with non-Hermiticity above a critical value.
Entanglement transitions to zero at the critical non-Hermiticity parameter γ=γc.
Non-maximal entanglement occurs for non-Hermiticity below the critical threshold.

Abstract

Theoretical analysis of a prototypical two-qubit effective non-Hermitian system characterized by asymmetric Heisenberg XY interactions in the absence of external magnetic fields demonstrates that maximal bipartite entanglement and quantum phase transitions can be induced exclusively through non-Hermiticity. At thermal equilibrium as T→0, the system attains maximal entanglement C=1 for values of the non-Hermiticity parameter greater than a critical value γγc=J1−δ2, where J denotes the exchange interaction and δ represents the anisotropy of the system; conversely, for γγc, entanglement is nonmaximal and given by C=1−(γ/J)2. The entanglement undergoes a discontinuous transition to zero precisely at γ=γc. This phase transition originates from the closing of the energy gap at a non-Hermiticity-driven ground state degeneracy, which is fundamentally different from an exceptional point.

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Non-Hermiticity induced thermal entanglement phase transition

Key Points

Abstract

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