Issue 17, 2022

Phonon-induced relaxation mechanisms are changed by a chelating effect in a CoII single-ion magnet

Abstract

It is well known that phonon-induced relaxation processes play a significant role in accelerating magnetization relaxation in the low-temperature regime. Unfortunately, many SIMs (single-ion magnets) suffer from being quenched by these mechanisms such that neither out-of-phase signals nor magnetization hysteresis can be readily observed. Nevertheless, because it involves molecular motions at low-frequency (low-energy) levels, methods for synthetically controlling this factor have not yet been addressed by chemists. In this study, we prepared a series of three compounds in which one contains a rigid chelating ligand, and the other two contain analogous ligands that can coordinate more liberally. To our surprise, compound 1, with a rigid chelating ligand, displayed promising SIM behavior with out-of-phase signals up to 11 K in a zero d.c. magnetic field at an a.c. frequency of 1000 Hz. The other two (2 and 3) with dangling ligands failed to show significant out-of-phase signals until an extra d.c. field was applied. The results of magnetization relaxation studies suggest that the phonon-induced relaxation processes play an essential role in 2 and 3, even at very low temperatures. Nevertheless, the rigid chelating ligand in 1 prevents the molecule from being involved in phonon-induced relaxation processes that seriously interfere with the magnetization relaxation up to 5.6 K. Therefore, we concluded that the presence of a rigid chelating ligand can efficiently change the phonon-induced relaxation processes at low temperatures.

Graphical abstract: Phonon-induced relaxation mechanisms are changed by a chelating effect in a CoII single-ion magnet

Supplementary files

Article information

Article type
Paper
Submitted
18 Oct 2021
Accepted
26 Mar 2022
First published
11 Apr 2022

Dalton Trans., 2022,51, 6646-6653

Phonon-induced relaxation mechanisms are changed by a chelating effect in a CoII single-ion magnet

Y. Lou, B. Lin, C. Wu, S. Chien and E. Yang, Dalton Trans., 2022, 51, 6646 DOI: 10.1039/D1DT03515K

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