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Enhancing Magnetic Hysteresis in Single-Molecule Magnets by Ligand Functionalization

Ke‐Xin Yu, Jon G. C. Kragskow, You‐Song Ding, Yuan‐Qi Zhai, Daniel Reta, Nicholas F. Chilton, Yan‐Zhen Zheng

2020Chem166 citationsDOIOpen Access PDF

Abstract

Design criteria for dysprosium(III) single-molecule magnets (SMMs) with large thermal energy barriers to magnetic reversal have been established and proven, and the challenge to enhance performance is in understanding and controlling electron-vibration coupling that is the origin of magnetic reversal. We have prepared an SMM, [Dy(L)2(py)5][BPh4] 1 (HL = (S)-(-)-1-phenylethanol), based on the archetype [Dy(OtBu)2(py)5][BPh4] 2. Compounds 1 and 2 have similarly large energy barriers of Ueff = 1,130(20) cm−1 and Ueff = 1,250(10) cm−1, and yet 1 shows magnetic hysteresis at a far higher temperature of 22 K cf. TH = 4 K for 2. Ab initio calculation of the electron-vibration coupling and spin dynamics shows that substitution of the alkoxide ligand in fact enhances relaxation over the energy barrier for 1 compared with 2, in agreement with experiment, and that the higher temperature of magnetic hysteresis likely owes to reduced quantum tunneling at low temperatures.

Topics & Concepts

DysprosiumHysteresisAb initioMagnetMagnetic hysteresisMaterials scienceCrystallographyRelaxation (psychology)AlkoxideCoupling (piping)Quantum tunnellingLigand (biochemistry)Condensed matter physicsAb initio quantum chemistry methodsMagnetismMoleculeChemistryMagnetizationPhysicsMagnetic fieldInorganic chemistryMetallurgyPsychologyCatalysisBiochemistrySocial psychologyQuantum mechanicsReceptorOrganic chemistryMagnetism in coordination complexesLanthanide and Transition Metal ComplexesOrganic and Molecular Conductors Research