Litcius/Paper detail

Tuning structural and electronic properties of metal-organic framework 5 by metal substitution and linker functionalization

Joshua Edzards, Holger‐Dietrich Saßnick, Julia Santana-Andreo, Caterina Cocchi

2024The Journal of Chemical Physics10 citationsDOI

Abstract

The chemical flexibility of metal-organic frameworks (MOFs) offers an ideal platform to tune structure and composition for specific applications, from gas sensing to catalysis and from photoelectric conversion to energy storage. This variability gives rise to a large configurational space that can be efficiently explored using high-throughput computational methods. In this work, we investigate from first principles the structural and electronic properties of MOF-5 variants obtained by replacing Zn with Be, Mg, Cd, Ca, Sr, and Ba and by functionalizing the originally H-passivated linkers with CH3, NO2, Cl, Br, NH2, OH, and COOH groups. To build and analyze the resulting 56 structures, we employ density-functional theory calculations embedded in an in-house developed library for automatized calculations. Our findings reveal that structural properties are mainly defined by metal atoms and large functional groups, which distort the lattice and modify coordination. The formation energy is largely influenced by functionalization and enhanced by COOH and OH groups, which promote the formation of hydrogen bonds. The charge distribution within the linker is especially influenced by functional groups with electron-withdrawing properties, while the metal nodes play a minor role. Likewise, the bandgap size is crucially determined by ligand functionalization. The smallest gaps are found with NH2 and OH groups, which introduce localized orbitals at the top of the valence band. This characteristic makes these functionalizations particularly promising for the design of MOF-5 variants with enhanced gas uptake and sensing properties.

Topics & Concepts

Surface modificationDensity functional theoryBand gapMetal-organic frameworkAtomic orbitalValence (chemistry)LinkerChemistryMetalMaterials scienceComputational chemistryChemical physicsNanotechnologyCombinatorial chemistryPhysical chemistryOrganic chemistryElectronComputer scienceOptoelectronicsPhysicsAdsorptionQuantum mechanicsOperating systemMetal-Organic Frameworks: Synthesis and ApplicationsMachine Learning in Materials ScienceX-ray Diffraction in Crystallography