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Molecular understanding of Ni <sup>2+</sup> -nitrogen family metal-coordinated hydrogel relaxation times using free energy landscapes

Eesha Khare, Seth Cazzell, Jake Song, Niels Holten‐Andersen, Markus J. Buehler

2023Proceedings of the National Academy of Sciences19 citationsDOIOpen Access PDF

Abstract

Incorporating dynamic metal-coordination bonds as cross-links into synthetic materials has become attractive not only to improve self-healing and toughness, but also due to the tunability of metal-coordination bonds. However, a priori determination of bond lifetime of metal-coordination complexes, especially important in the rational design of metal-coordinated materials with prescribed properties, is missing. We report an empirical relationship between the energy landscape of metal-coordination bonds, simulated via metadynamics, and the resulting macroscopic relaxation time in ideal metal-coordinated hydrogels. Importantly, we expand the Arrhenius relationship between the macroscopic hydrogel relaxation time and metal-coordinate bond activation energy to include width and landscape ruggedness identified in the simulated energy landscapes. Using biologically relevant Ni 2+ -nitrogen coordination complexes as a model case, we demonstrate that the quantitative relationship developed from histidine-Ni 2+ and imidazole-Ni 2+ complexes can predict the average relaxation times of other Ni 2+ -nitrogen coordinated networks. We anticipate the quantitative relationship presented here to be a starting point for the development of more sophisticated models that can predict relaxation timescales of materials with programmable viscoelastic properties.

Topics & Concepts

MetadynamicsChemical physicsEnergy landscapeArrhenius equationRelaxation (psychology)MetalActivation energyMaterials scienceCoordination numberSelf-healing hydrogelsMolecular dynamicsComputational chemistryChemistryThermodynamicsPhysical chemistryIonPolymer chemistryPhysicsOrganic chemistryMetallurgySocial psychologyPsychologyProtein Structure and DynamicsPolymer Surface Interaction StudiesLipid Membrane Structure and Behavior
Molecular understanding of Ni <sup>2+</sup> -nitrogen family metal-coordinated hydrogel relaxation times using free energy landscapes | Litcius