Molecular Nanomagnet $\text{Cu}^\text{II}\text{Ni}^\text{II}\text{Cu}^\text{II}$ as Resource for Quantum Entanglement, Coherence, and Spin Squeezing

We investigate key quantum characteristics of the mixed spin-(1/2,1,1/2) Heisenberg trimer under the influence of an external magnetic field. Specifically, we analyze the distributions of bipartite and tripartite entanglement quantified through the respective negativities, the $l_1$-norm of coherence, and spin squeezing with the help of rigorous analytical and numerical methods. Our findings suggest that the heterotrinuclear molecular nanomagnet $[\{\text{Cu}^\text{II}\text{L}\}_2\text{Ni}^\text{II}(\text{H}_2\text{O})_2](\text{ClO}_4)_23\text{H}_2\text{O}$, which represents an experimental realization of the mixed spin-(1/2,1,1/2) Heisenberg trimer, exhibits a significant bipartite entanglement between $\text{Cu}^\text{II}$ and $\text{Ni}^\text{II}$ magnetic ions along with robust tripartite entanglement among all three constituent magnetic ions. The significant bipartite and tripartite entanglement persists even at relatively high temperatures up to $37\,\text{K}$ and magnetic fields up to $50\,\text{T}$, whereby the coherence is maintained even at elevated temperatures. In addition, we investigate the spin squeezing parameter within thermal states of the spin-(1/2,1,1/2) Heisenberg trimer. Our exact results reveal optimal conditions for achieving the highest degree of the spin squeezing, which are achieved at zero magnetic field around $T \approx 30\,\text{K}$.
Comment: 15 pages, 6 figures