2022
DOI: 10.1007/978-3-031-07658-9_4
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NAST: Nonadiabatic Statistical Theory Package for Predicting Kinetics of Spin-Dependent Processes

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“…The design of new lanthanide-based single-molecule magnets (Ln-based SMMs) is a very active field of research driven by their potential applications in spintronics ,, and high-density information storage. , Magnetic properties of Ln-based SMMs arise from the large electron spin (S) and orbital angular momentum (L) of lanthanide ions. The strong spin–orbit coupling (SOC) combines S and L into the total angular momentum (pseudospin) J that defines magnetization of SMMs. To be useful for practical applications, an SMM must be characterized by slow relaxation of magnetization (long pseudospin relaxation time), which requires a strong anisotropy of the crystal field around Ln ion and a minimal coupling between the pseudospin and molecular vibrations. , Therefore, the design strategy of Ln-based SMMs involves developing ligands that would produce a strong anisotropic environment and reduce couplings between the spin and vibrational states of the resulting complex.…”
mentioning
confidence: 99%
“…The design of new lanthanide-based single-molecule magnets (Ln-based SMMs) is a very active field of research driven by their potential applications in spintronics ,, and high-density information storage. , Magnetic properties of Ln-based SMMs arise from the large electron spin (S) and orbital angular momentum (L) of lanthanide ions. The strong spin–orbit coupling (SOC) combines S and L into the total angular momentum (pseudospin) J that defines magnetization of SMMs. To be useful for practical applications, an SMM must be characterized by slow relaxation of magnetization (long pseudospin relaxation time), which requires a strong anisotropy of the crystal field around Ln ion and a minimal coupling between the pseudospin and molecular vibrations. , Therefore, the design strategy of Ln-based SMMs involves developing ligands that would produce a strong anisotropic environment and reduce couplings between the spin and vibrational states of the resulting complex.…”
mentioning
confidence: 99%