Quantum correlations and coherence in a two-qubit anisotropic XY under magnetic field

Abstract

We study thermal quantum correlations and coherence in Heisenberg XY model with anisotropic interactions under a uniform magnetic field B . Using concurrence C, local quantum uncertainty (LQU), Bell-Clauser-Horne-Shimony-Holt (CHSH) nonlocality B, and coherence Cl as quantifiers, we analyze how magnetic anisotropy δm , coupling anisotropy δc , Dzyaloshinskii-Moriya (DM) interaction D , temperature T , and magnetic field B modulate quantum resources. At low temperatures and relevant magnetic fields, the entanglement is maximized, but exhibits sudden death for δm = 0 , which turns into a smooth decay as δm increases, highlighting its stabilizing role. LQU shows that stronger anisotropy suppresses quantum correlations, while B induces a non-monotonic response peaking at a critical field Bc . Bell-CHSH nonlocality violations ( B > 2 ) persist below Bc , but thermal noise ( T ≥ 1 ) suppresses them. Coherence Cl is most robust to thermal fluctuations, especially for high \( δm \), which also dampens abrupt quantum phase transitions. The DM interaction is essential for entanglement generation, with D and anisotropy synergistically enhancing correlation resilience. We identify a hierarchy of thermal degradation: nonlocality ( B ) vanishes first, followed by entanglement ( C ), then general quantum correlations (LQU), while coherence Cl persists the longest. These results demonstrate tunable control of quantum resources via anisotropy and external parameters, providing insights for the design of robust spin-based quantum technologies.