Mixed-Ligand-Architected 2D Co(II)-MOF Expressing a Novel Topology for an Efficient Photoanode for Water Oxidation Using Visible Light

The structural diversity of Co­(II) metal centers is known to influence their physicochemical properties. A novel two-dimensional (2D) Co­(II)-MOF {[Co5(HL)4(dpp)2(H2O)2(μ-OH)2]·21H2O}n has been designed and synthesized by adopting a mixed-ligand strategy, using 1,3-di­(4-pyridyl)­propane (dpp) colinker with a flexible spacer H3L (H3L: 5-(2 carboxybenzyloxy)­isophthalic acid). Co­(II)-MOF features a 2D network, which is further interpenetrated among the equivalent sets and therefore results in a 3D supramolecular network. Topologically, the entire network can be viewed as a (3,4,8)-connected three-nodal net with the extended point symbol of {4.5.7}­4­{412.52.710.94}­{52.8.92.10}­2, duly assigned to the novel topological type smm2. The functional utility of Co­(II)-MOF is demonstrated by employing it toward oxygen evolution reaction (OER) in a photoelectrochemical cell, exhibiting appreciable photocurrents of up to 5.89 mA/cm2 when used as an anode in a photoelectrochemical cell, while also displaying encouraging electrocatalytic currents of 9.32 mA/cm2 (at 2.01 V vs RHE) for the OER. Moreover, detailed electrochemical impedance spectroscopy studies confirm enhanced charge-transfer kinetics and improved conductivity under illumination with minimal effect of interfacial phenomena. This work provides a reference for the expanding field of research into applications of MOF materials and establishes MOF materials as favorable candidates for sustainable and efficient design of electrodes for water splitting.