Force-Activated Spin-Crossover in Fe and Co Transition Metal Mechanophores.

Transition metal mechanophores exhibiting force-activated spin-crossover are attractive design targets, yet large-scale discovery of them has not been pursued due in large part to the time-consuming nature of trial-and-error experiments. Instead, we leverage density functional theory (DFT) and external force explicitly included (EFEI) modeling to study a set of 395 feasible Fe and Co mechanophore candidates with tridentate ligands that we curate from the Cambridge Structural Database. Among nitrogen-coordinating low-spin complexes, we observe the prevalence of spin crossover at moderate force, and we identify 155 Fe and Co spin-crossover mechanophores and derive their threshold force for low-spin to high-spin transition (). The calculations reveal strong correlations of with spin-splitting energies and coordination bond lengths, facilitating rapid prediction of using force-free DFT calculations. Then, among all Fe and Co spin-crossover mechanophores, we further identity 11 mechanophores that combine labile spin-crossover and good mechanical robustness that are thus predicted to be the most versatile for force-probing applications. We discover two classes of symmetric complexes comprising specific heteroaromatic rings within extended π-conjugation that give rise to Fe mechanophores with these characteristics. We expect the set of spin-crossover mechanophores, the design principles, and the computational approach to be useful in guiding the high-throughput discovery of transition metal mechanophores with diverse functionalities and broad applications, including mechanically activated catalysis.