Fadwa Benabdallah, M. Y. Abd-Rabbou, Mohammed Daoud, Saeed Haddadi
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Quantum Information Resources in Spin-1 Heisenberg Dimer Systems
We explore the quantum information resources within bipartite pure and mixed
states of the quantum spin-1 Heisenberg dimer system, considering some
interesting factors such as the $l_{1}$-norm of quantum coherence, relative
coherence, entanglement, and steering, influenced by the magnetic field and
uniaxial single-ion anisotropy. Through a thorough investigation, we derive the
system's density operator at thermal equilibrium and establish a mathematical
framework for analyzing quantum correlation metrics. Our results unveil the
system's behavior at absolute zero temperature, revealing quantum
antiferromagnetic, ferromagnetic, and ferrimagnetic phase transitions governed
by the magnetic field and anisotropy parameters. We further observe
temperature's role in transitioning the system towards classical states,
impacting coherence, entanglement, and steering differently. Notably, we find
that increasing the exchange anisotropy parameter can reinforce quantum
correlations while adjusting the uniaxial single-ion anisotropy parameter
influences the system's quantumness, particularly when positive. Some
recommendations to maximize quantum coherence, entanglement, and steering
involve temperature reduction, increasing the exchange anisotropy parameter,
and carefully managing the magnetic field and uniaxial single-ion anisotropy
parameter, highlighting the intricate interplay between these factors in
maintaining the system's quantum properties.