Uncovering the correlations between the structure and valence tautomerism in Co(Dioxolene)2Py2 crystals
Marcelo F. F. Alecrim, Carlos B. Pinheiro, Simone S. Alexandre

TL;DR
This study explores how the structure of a cobalt complex influences its ability to switch between two electronic states, revealing a key role for molecular torsion and crystal packing.
Contribution
The paper identifies a direct correlation between pyridine plane torsion angles and valence tautomerism in Co(dioxolene)2(Py)2 crystals.
Findings
Only the 2:1 complex/solvent ratio exhibits valence tautomerism, while others remain in the low-spin state.
A torsion angle of ∼17.5° between pyridine planes and dioxolene centroids correlates with the spin state transition.
DFT calculations using LDA functional accurately reproduce experimental magnetic susceptibility and structural changes.
Abstract
Valence tautomers are electronically labile compounds that can switch between two distinct energy states with two different electronic distributions, which modifies the physical properties of the compound. This interconversion is triggered by external stimuli, such as temperature increase, pressure, application of an electric field, light incidence, and others [1,2]. The present study aims to investigate valence tautomerism (VT) characteristics in trans pyridine-solvated Co(dioxolene)2(Py)2 complexes, where dioxolene represents 3,5-di-tert-butyl semiquinone and 3,5- di-tert-butyl catecholate, and Py stands for pyridine. Each dioxolene form is associated with a specific energy state: 3,5-di-tert-butyl catecholate corresponds to the low-spin (LS) state, while 3,5-di-tert-butyl semiquinone is in the high-spin (HS) state, both of which are stable in given temperatures. In this compound, the…
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Taxonomy
TopicsAdvanced Chemical Physics Studies · Magnetism in coordination complexes · Inorganic Chemistry and Materials
