Methods and Models of Theoretical Calculation for Single-Molecule Magnets

Luo, Qian‐Cheng; Zheng, Yan‐Zhen

doi:10.3390/magnetochemistry7080107

Cited by 15 publications

(16 citation statements)

References 66 publications

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“…Some of the most elusive representations that may mislead research, for example, arise from the phenomenological superposition of incompatible with respect to their physical background microscopic effective spin models, with the aim to generate a single multispin Hamiltonian or introduce a giant spin one. , One multispin Hamiltonian that inconsistently combines microscopic effective spin models reads Ĥ = ∑ i , j J i j boldŝ i · boldŝ j + ∑ i ŝ i · boldD i i · boldŝ i + ∑ i , j d i j · ( ŝ i × ŝ j ) where i ≠ j run over all effective spin centers in the molecular nanomagnet, J ij are the corresponding exchange couplings, D ii are the one-site traceless symmetric tensors and d ij are the vectors associated with the Dzyaloshinskii Moriya interactions, i.e. the antisymmetric exchange ones.…”

Section: Critical Theoretical Aspectsmentioning

confidence: 99%

“…The ambiguity occurring from the improper combination of different complete effective spin models, especially the bilinear exchange Hamiltonian 19 with the conventional ZFS one, 20,22 is beyond the scope of this review and will be discussed in a separate paper. 14 On the other hand, the direct definition 5,17,23 of a relation between molecular nanomagnets' FS parameters and the classical magnetocrystalline anisotropy parameters from the phenomenological theory of MA in solids 24−26 strongly misshapes our understanding about the underlying quantum magnetization-reversal processes. If not properly applied, this definition yields an inconsistent theoretical approach for calculating MA and, hence, an unjustified relation between the phenomenological anisotropy constant "K" and FS parameters such as the axial D and rhombic E ones used to characterize ZFS in transition metal complexes.…”

Section: Critical Theoretical Aspectsmentioning

confidence: 99%

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Single-Ion Magnets with Giant Magnetic Anisotropy and Zero-Field Splitting

Georgiev

Chamati

2022

ACS Omega

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The design of mononuclear molecular nanomagnets exhibiting a huge energy barrier to the reversal of magnetization have seen a surge of interest during the last few decades due to their potential technological applications. More specifically, singleion magnets are peculiarly attractive by virtue of their rich quantum behavior and distinct fine structure. These are viable candidates for implementation as single-molecule high-density information storage devices and other applications in future quantum technologies. The present review presents the comprehensive state of the art in the topic of single-ion magnets possessing an eminent magnetization-reversal barrier, very slow magnetic relaxation and high blocking temperature. We turn our attention to the achievements in the synthesis of 3d and 4f single-ion magnets during the last two decades and discuss the observed magnetostructural properties underlying the anisotropy behavior and the ensuing remanence. Furthermore, we highlight the fundamental theoretical aspects to shed light on the complex behavior of these nanosized magnetic entities. In particular, we focus on key notions, such as zero-field splitting, anisotropy energy and quantum tunneling of the magnetization and their interdependence.

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Section: Critical Theoretical Aspectsmentioning

confidence: 99%

Section: Critical Theoretical Aspectsmentioning

confidence: 99%

Single-Ion Magnets with Giant Magnetic Anisotropy and Zero-Field Splitting

Georgiev

Chamati

2022

ACS Omega

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“…The rapid growth of the digital ecosystem in recent decades has made the need for powerful processors and high-density data storage systems more apparent, and single-molecule magnets (SMMs) are considered as having great potential in this regard. − The last three decades have seen tremendous progress in this field, both on the synthetic side as well as in the development of computational methods and new advanced spectroscopic techniques that provide a direct correlation between experimental findings and theoretical models. − In recent years, some excellent high-performance 3d- and 4f-ion-based SMMs have been reported that possess a very high effective energy barrier for magnetization reversal ( U eff ) and blocking temperature ( T B ). − In the case of SMMs based on 3d metal ions, magnetic bistability originates from an energy barrier ( U eff ) that in turn results from the zero-field splitting (ZFS) of the ground spin multiplet. Current synthetic strategies thus target systems that minimize quenching of the angular momentum L , usually via ligand field design that preserves degeneracy of the ( d x 2 – y 2 , d xy ) and/or ( d xz , d yz ) orbital pairs.…”

Section: Introductionmentioning

confidence: 99%

Multi-Technique Experimental Benchmarking of the Local Magnetic Anisotropy of a Cobalt(II) Single-Ion Magnet

Gupta

Nielsen

Thiel

et al. 2023

JACS Au

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A comprehensive understanding of the ligand field and its influence on the degeneracy and population of d-orbitals in a specific coordination environment are crucial for the rational design and enhancement of magnetic anisotropy of single-ion magnets (SIMs). Herein, we report the synthesis and comprehensive magnetic characterization of a highly anisotropic CoII SIM, [L2Co](TBA)2 (L is an N,N′-chelating oxanilido ligand), that is stable under ambient conditions. Dynamic magnetization measurements show that this SIM exhibits a large energy barrier to spin reversal U eff > 300 K and magnetic blocking up to 3.5 K, and the property is retained in a frozen solution. Low-temperature single-crystal synchrotron X-ray diffraction used to determine the experimental electron density gave access to Co d-orbital populations and a derived U eff, 261 cm–1, when the coupling between the d x 2 – y 2 and dxy orbitals is taken into account, in very good agreement with ab initio calculations and superconducting quantum interference device results. Powder and single-crystal polarized neutron diffraction (PNPD, PND) have been used to quantify the magnetic anisotropy via the atomic susceptibility tensor, revealing that the easy axis of magnetization is pointing along the N–Co–N′ bisectors of the N,N′-chelating ligands (3.4° offset), close to the molecular axis, in good agreement with complete active space self-consistent field/N-electron valence perturbation theory to second order ab initio calculations. This study provides benchmarking for two methods, PNPD and single-crystal PND, on the same 3d SIM, and key benchmarking for current theoretical methods to determine local magnetic anisotropy parameters.

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“…Depending on the dimensionality of the compounds, the magnetic systems are categorized into single-molecule magnets (SMMs, 0D compounds) [ 15 , 16 , 17 , 18 , 19 , 20 , 21 ] and single-chain magnets (SCMs, 1D compounds) [ 21 , 22 , 23 , 24 , 25 , 26 , 27 ]. Temperature-dependent magnetic dynamics of SMMs and SCMs is defined by the energy barrier for magnetization reversal, U eff , and blocking temperature T b , below which the magnetization is blocked and retained for a long period of time [ 16 , 23 , 26 , 28 , 29 , 30 ]. However, the mechanism underlying the slow relaxation and the origin of the energy barrier in 0D and 1D magnetic systems is different.…”

Section: Introductionmentioning

confidence: 99%

“…However, the mechanism underlying the slow relaxation and the origin of the energy barrier in 0D and 1D magnetic systems is different. In SMMs, negative uniaxial magnetic anisotropy ( D < 0), together with high-spin ground state ( S ), is responsible for a double-well potential with the energy barrier U eff = Δ = | D | S 2 for integer S and | D |( S 2 −1/4) for half-integer S [ 1 , 3 , 28 ]. In SCMs, the barrier contains an additional energy term, Δ ξ , resulting from exchange coupling ( J ) between the magnetic ions, U eff = k Δ ξ + Δ, where k = 1 for finite or 2 for infinite chain [ 24 , 26 , 27 , 31 , 32 ].…”

Section: Introductionmentioning

confidence: 99%

Interplay of Anisotropic Exchange Interactions and Single-Ion Anisotropy in Single-Chain Magnets Built from Ru/Os Cyanidometallates(III) and Mn(III) Complex

2023

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Two novel 1D heterobimetallic compounds {[MnIII(SB2+)MIII(CN)6]·4H2O}n (SB2+ = N,N’-ethylenebis(5-trimethylammoniomethylsalicylideneiminate) based on orbitally degenerate cyanidometallates [OsIII(CN)6]3− (1) and [RuIII(CN)6]3− (2) and MnIII Schiff base complex were synthesized and characterized structurally and magnetically. Their crystal structures consist of electrically neutral, well-isolated chains composed of alternating [MIII(CN)6]3- anions and square planar [MnIII(SB2+)]3+ cations bridged by cyanide groups. These -ion magnetic anisotropy of MnIII centers. These results indicate that the presence of compounds exhibit single-chain magnet (SCM) behavior with the energy barriers of Δτ1/kB = 73 K, Δτ2/kB = 41.5 K (1) and Δτ1/kB = 51 K, Δτ2 = 27 K (2). Blocking temperatures of TB = 2.8, 2.1 K and magnetic hysteresis with coercive fields (at 1.8 K) of 8000, 1600 Oe were found for 1 and 2, respectively. Theoretical analysis of the magnetic data reveals that their single-chain magnet behavior is a product of a complicated interplay of extremely anisotropic triaxial exchange interactions in MIII(4d/5d)–CN–MnIII fragments: −JxSMxSMnx−JySMySMny−JzSMzSMnz, with opposite sign of exchange parameters Jx = −22, Jy = +28, Jz = −26 cm−1 and Jx = −18, Jy = +20, Jz = −18 cm–1 in 1 and 2, respectively) and singleorbitally degenerate [OsIII(CN)6]3− and [RuIII(CN)6]3− spin units with unquenched orbital angular momentum in the chain compounds 1 and 2 leads to a peculiar regime of slow magnetic relaxation, which is beyond the scope of the conventional Glaubers’s 1D Ising model and anisotropic Heisenberg model.

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Methods and Models of Theoretical Calculation for Single-Molecule Magnets

Cited by 15 publications

References 66 publications

Single-Ion Magnets with Giant Magnetic Anisotropy and Zero-Field Splitting

Single-Ion Magnets with Giant Magnetic Anisotropy and Zero-Field Splitting

Multi-Technique Experimental Benchmarking of the Local Magnetic Anisotropy of a Cobalt(II) Single-Ion Magnet

Interplay of Anisotropic Exchange Interactions and Single-Ion Anisotropy in Single-Chain Magnets Built from Ru/Os Cyanidometallates(III) and Mn(III) Complex

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