Thermodynamics of the Oxygen Evolution Electrocatalysis in Metal-Organic Frameworks

TL;DR

This study uses DFT to analyze the thermodynamics of oxygen evolution in MOFs, revealing heterogeneity of reaction sites and the impact of linker functionalization, which could surpass limitations of traditional catalysts.

Contribution

It introduces a thermodynamic analysis of MOF-based OER catalysts, highlighting the effects of functionalization and heterogeneity on catalytic performance.

Findings

MOF functionalization significantly affects hydroperoxyl binding energy.

Heterogeneity of reaction sites distinguishes MOF thermodynamics from homogeneous catalysts.

The BDC+NH2 MOF has the lowest predicted over-potential of 3.03 eV.

Abstract

Metal-organic frameworks (MOFs) provide a versatile and tailorable material platform that embody many desirable attributes for photocatalytic water-splitting. The approach taken in this study was to use Density Functional Theory (DFT) to predict the thermodynamic energy barriers of the oxygen evolution reaction (OER) for three MOF functionalizations. A Zr-MIL-125 MOF design was selected for this study that incorporates three linker designs, a 1,4-benzenedicarboxylate (BDC), BDC functionalized with an amino group (BDC+NH2), and BDC functionalized with nitro group (BDC+NO2). The study found several key differences between homogeneous planar catalyst thermodynamics and MOF based thermodynamics, the most significant being the non-unique or heterogeneity of reaction sites. Additionally, the funcationalization of the MOF was found to significantly influence the hydroperoxyl binding energy, which proves to be the largest hurdle for both oxide and MOF based catalyst. Both of these findings provide evidance that many of the limitations precluding planar homogeneous catalysts can be surpassed with a MOF based catalyst. While none of the MOF designs selected for this study out-performed state-of-the-art oxide based catalysts, the BDC+NH2 proved to be the best with a predicted over-potential for spontaneous OER evolution to be 3.03eV.