Semiconductor-hydrophobic material interfaces as a new active site paradigm for photocatalytic degradation of perfluorocarboxylic acids

Photocatalytic degradation of long-chain perfluorocarboxylic acid (PFCA) water contaminants has been reported for numerous of semiconductors, including composite TiO2 particles decorated with graphitic carbon co-catalysts. While pristine TiO2 degrades PFCAs inefficiently, the carbon components purportedly enhance activity due to their conductive nature and resultant charge separation enhancement. Yet herein, we present evidence that the catalytic activity of a graphene oxide (GO)-TiO2 composite from the literature arose not due to from charge separation, but to a unique mode of PFCA adsorption occurring at the interface of TiO2 and hydrophobic GO. Photocatalytic degra-dation rates by GO-TiO2 were compared to those of composites containing nonconductive polymer microparticles (polyethylene, polytetrafluoroethylene). Results showed that polymer-TiO2 composites performed as well as GO-TiO2 in degrading both perfluorooctanoic acid and oxalate, a common hole scavenger. Thus, the enhanced activity may occur for any TiO2-hydrophobic interface, regardless of co-catalyst conductivity. Furthermore, compared to an unmodified reference catalyst, chain length dependence of PFCA degradation by a polymer-TiO2 composite was found to be less severe, with greater activity toward short-chain species indicating enhanced adsorption behavior. Potential adsorption mechanisms are presented, along with broader implications toward improving the applica-bility of heterogeneous processes toward a wider range of perfluoroalkyl contaminants.

Automated summary

The catalytic activity of a graphene oxide (GO)-TiO2 composite was found to be attributed to a unique mode of PFCA adsorption occurring at the interface of TiO2 and hydrophobic GO, rather than charge separation. The GO-TiO2 composite showed comparable photocatalytic degradation rates to composites containing nonconductive polymer microparticles, indicating that the enhanced activity may occur at any TiO2-hydrophobic interface. Moreover, the polymer-TiO2 composite exhibited less severe chain length dependence in PFCA degradation, suggesting improved adsorption behavior.