Analysis of vibronic coupling in a 4f molecular magnet with FIRMS

Kragskow, Jon G. C.; Marbey, Jonathan; Buch, Christian Dirk; Nehrkorn, Joscha; Ozerov, Mykhaylo; Piligkos, Stergios; Hill, Stephen; Chilton, Nicholas F.

doi:10.1038/s41467-022-28352-2

Cited by 40 publications

(46 citation statements)

References 55 publications

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“…We have shown herein that long phase memory times can be achieved in purely f-electron systems essentially devoid of orbital angular momentum since local fluctuations of the LF cannot couple via magnetoelastic coupling terms to the wave functions of the electronic system. These results are in agreement with previous studies on d- or f-shell molecular systems where isotropic states, thus devoid of orbital angular momentum, have been probed. ,, Furthermore, they are also in agreement with recent experimental and theoretical studies in which we demonstrated the importance of the magnetoelastic coupling and the role of the trigonal symmetry to the dynamic magnetic properties of the isostructural (displaying thus the same phonon spectrum) Yb(trensal) complex . In addition, in previous coherent dynamics studies of Yb(trensal), we have shown that the ground term displays a phase memory time of a few hundred nanoseconds for Yb 0.07 Lu 0.93 (trensal) at X-band, which gets T 1 limited and of the order of 0.1 μs at around 20 K. Preliminary measurements on single crystals of Yb 0.01 Lu 0.99 (trensal) at 240 GHz (Figure S14) show similar T m characteristics as those previously determined for Yb(III) at X-band .…”

Section: Resultssupporting

confidence: 93%

Spin–Lattice Relaxation Decoherence Suppression in Vanishing Orbital Angular Momentum Qubits

et al. 2022

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Multifrequency electron paramagnetic resonance spectroscopy on oriented single crystals of magnetically dilute Gd(III) ions in Gd0.004Y0.996(trensal) is used to determine the Hamiltonian parameters of the ground 8 S 7/2 term and its phase memory time, T m, characterizing its coherent spin dynamics. The vanishing orbital angular momentum of the 8 S 7/2 term makes it relatively insensitive to spin–lattice relaxation mediated by magnetoelastic coupling and leads to a T m of 12 μs at 3 K, which is not limited by spin–lattice relaxation.

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Section: Resultssupporting

confidence: 93%

Spin–Lattice Relaxation Decoherence Suppression in Vanishing Orbital Angular Momentum Qubits

et al. 2022

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“…Fitting results suggest that spin-lattice interaction dominates in the magnetization reversal process, which might correlate with the Raman signal observed in the LF region with the vibrational energy of 60 cm -1 or lower, suggesting the presence of phonon required to help the spin relaxation to happen through the Raman mechanism. [17] The obtained Orbach energy barrier for Dy 0.02 Y 0.98 Au is 90.83 K (63.1 cm -1 ) following Equation (E3), corroborating the energy gap between the m J states as predicted through ab initio calculation and underestimating by 63 cm -1 calculated with high-resolution emission spectra (Figure S23 and Table S15, Supporting Information). The ground state composition for Dy(III) ions computed by replacing neighboring Dy(III) ions with Y(III) ions reveals that it has an anisotropic magnetic easy axis (g z = 18.56); however accompanied by nonnegligible transversal components hampering the zero-dc-field slow magnetic relaxation (Figure S33, Table S15, Supporting Information).…”

Section: Magnetic Propertiessupporting

confidence: 76%

“…For such opto-magnetic lanthanide complexes, studying the vibrational signature in the LF region for Raman active modes through LF Raman spectroscopy can enhance our understanding of the dependence of physical properties (magnetic, optical) on structural changes. [17] Raman spectroscopy in the LF region has been used to detect various bonds of Au atoms in gold clusters, vibrational modes of pharmaceutical crystals, and phonons of graphene. [18] In this regard, Raman spectroscopy applied to a temperature sensor in the LF region (especially below 1 THz) has not been reported.…”

Section: Introductionmentioning

confidence: 99%

Ratiometric Raman and Luminescent Thermometers Constructed from Dysprosium Thiocyanidometallate Molecular Magnets

Kumar

Stefańczyk

Chorąży

et al. 2022

Advanced Optical Materials

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Molecular crystals acting as temperature sensors, designed for multiple measurement techniques, can be a promising pathway for self‐calibrating thermometers. The molecular assemblies [DyxIIIY1–xIII(phen)2(μ‐OH)2(H2O)2]·[AuI(SCN)2]2·phen·0.5MeCN·0.5H2O (x = 0, 0.1, 0.02; phen = 1,10‐phenanthroline) which contain weakly bonded lanthanide(III) and Au(I) metal complexes are reported. They have Raman scattering in the low‐frequency (LF) region with sharp peaks, one of the prerequisites to design Raman thermometers. The Raman thermometric behaviors are characterized by three vibrational bands, and their thermal sensitivity is compared with their emission thermometric ability. The LF phonon linked with the Au···Au vibration helps increase the thermometric sensitivity of emission and Raman thermometers. Additionally, magnetically diluted complexes containing both Dy3+ and Y3+ ions are prepared to demonstrate the effect of temperature sensing capability through Raman and emission spectroscopy among isostructural mixed‐metal materials. Compounds are immersed inside various benchtop solvents to unravel the robustness and functioning of Raman thermometers. Furthermore, they reveal single‐molecule magnet properties, which disclose the effect of LF phonons on the spin relaxation process. Therefore, the reported molecular materials are Raman and luminescent thermometers, and they contain a molecular magnetic center with thiocyanidoaurate ions playing a critical role due to their emissive and Raman activities.

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“…The magnetization barrier is deduced from the spin Hamiltonian. Supposing that the relaxation follow an Orbach relaxation scheme, it corresponds to the experimental value [76,77,78,79]. It is related to the anisotropy of the coupling, but is not affected by the anisotropy of the central g-tensor.…”

Section: Discussionmentioning

confidence: 99%

Analysis of the Magnetic Coupling in a Mn(II)‐U(V)‐Mn(II) Single Molecule Magnet

Dey

Rajaraman

Bolvin

2022

Chemistry A European J

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{Mn(TPA)I}{UO2(Mesaldien)}{Mn(TPA)I}]I formula (here TPA = tris(2-pyridylmethyl)amine and Mesaldien = N,N'-(2-aminomethyl)diethylenebis(salicylidene imine)) reported by Mazzanti and coworkers (Chatelain et al. Angew. Chem. Int. Ed. 2014, 53, 13434) is so far the best Single Molecule Magnet (SMM) in the {3d-5f} class of molecules exhibiting barrier height of magnetization reversal as high as 81.0 K. In this work, we have employed a combination of ab initio CAS and DFT methods to fully characterize this compound and to extract the relevant spin Hamiltonian parameters. We show that the signs of the magnetic coupling and of the g-factors of the monomers are interconnected. The central magnetic unit [U V O2] + is described by a Kramers Doublet (KD) with negative g-factors, due to a large orbital contribution. The magnetic coupling for the {Mn(II)-U(V)} pair is modeled by an anisotropic exchange Hamiltonian: all components are ferromagnetic in terms of spin moments, the parallel component JZ twice larger as the perpendicular one J ⊥ . The spin density distribution suggests that spin polarization on the U(V) center favors the ferromagnetic coupling. Further, the JZ /J ⊥ ratio, which is related to the barrier height, was found to correlate to the corresponding spin contribution of the g-factors of the U(V) center. This correlation established for the first time offers a direct way to estimate this important ratio from the corresponding g S -values, which can be obtained using traditional ab initio packages and hence has a wider application to other {3d-5f} magnets. It is finally shown that the magnetization barrier height is tuned by the splitting of the [U V O2] + 5f orbitals.

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Analysis of vibronic coupling in a 4f molecular magnet with FIRMS

Cited by 40 publications

References 55 publications

Spin–Lattice Relaxation Decoherence Suppression in Vanishing Orbital Angular Momentum Qubits

Spin–Lattice Relaxation Decoherence Suppression in Vanishing Orbital Angular Momentum Qubits

Ratiometric Raman and Luminescent Thermometers Constructed from Dysprosium Thiocyanidometallate Molecular Magnets

Analysis of the Magnetic Coupling in a Mn(II)‐U(V)‐Mn(II) Single Molecule Magnet

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