The Effects of Ligand Substituents on the Character of Zn-Coordination in Zeolitic Imidazolate Frameworks

TL;DR

This study investigates how ligand substituents influence zinc coordination and electronic properties in zeolitic imidazolate frameworks, combining density-functional theory and X-ray spectroscopy to elucidate structure-property relationships.

Contribution

It provides new insights into the impact of ligand functionalization on zinc coordination and electronic structure in ZIFs, supported by combined theoretical and experimental analysis.

Findings

Ligand substituents affect Zn coordination polarization.

Functionalization has negligible impact on overall electronic structure.

Halogen terminations reduce the band-gap size.

Abstract

Due to their favorable properties and high porosity, zeolitic imidazolate frameworks (ZIFs) have recently received much limelight for key technologies such as energy storage, optoelectronics, sensorics, and catalysis. Despite the widespread interest in these materials, fundamental questions regarding the zinc coordination environment remain poorly understood. By focusing on zinc(II)2-methylimidazolate (ZIF-8) and its tetrahedrally coordinated analogs with Br-, Cl-, and H-substitution in the 2-ring position, we aim to clarify how variations in the local environment of Zn impact the charge distribution and the electronic properties of these materials. Our results from density-functional theory confirm the presence of a Zn coordinative bond with a large polarization that is quantitatively affected by different substituents on the organic ligand. Moreover, our findings suggest that the variations induced by the functionalization in the Zn coordination have a negligible effect on the electronic structure of the considered compounds. On the other hand, halogen terminations of the ligands lead to distinct electronic contributions in the vicinity of the frontier region which ultimately reduce the band-gap size by a few hundred meV. Experimental results obtained from X-ray absorption spectroscopy (Zn $K$-edge) confirm the trends predicted by theory and, together with them, contribute to a better understanding of the structure-property relationships that are needed to tailor ZIFs for target applications.