Related papers: Exploiting the presence of chiral spin states in molecular nanomagnets

Exploiting the presence of chiral spin states in molecular nanomagnets

URL: http://arxiv.org/abs/2501.11964v1
Date: Tue, 21 Jan 2025 08:23:12 GMT
Title: Exploiting the presence of chiral spin states in molecular nanomagnets
Authors: Aman Ullah, Ziqi Hu, Alejandro Gaita-Ariño,
Abstract summary: In a three-spin-center system, antiferromagnetic exchange interactions give rise to two ground-state doublets.<n>We explore the presence of spin-chirality in Lanthanide complexes that feature two magnetic centers.
Score: 47.41699406259656
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In a three-spin-center system, antiferromagnetic exchange interactions give rise to two ground-state doublets, each state within the doublet exhibiting distinct spin-spectrum chirality. This chirality becomes significant when external perturbations are introduced. We explored, from a theoretical perspective, the presence of spin-chirality in Lanthanide complexes that feature two magnetic centers. The applied electric-potential, couples to the system electric dipole moment ($\mu$), modifying the spin-orbit interaction ($\hat{L}.\hat{S}$). This modification is formally expressed through the Dzyaloshinskii-Moriya interaction (DMI), whose role is to selectively activate one spin state in the doublet pair, as confirmed by computing the scalar spin-chirality ($\chi$). To validate the presence of chiral spin states, we performed spin-dynamics simulations using the Liouville-von Neumann equation within the density matrix formalism. The initial state was prepared as a superposition $1/\sqrt{2}(\rho_{01}+\rho_{10})$, and its time evolution revealed that each state in the doublet acquires a distinct phase, indicating their residence in separate phase spaces. This also demonstrated that the fidelity of the initial prepared state remains stable over an extended period.

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