Litcius/Paper detail

Application of Heterojunction Ni–Sb–SnO<sub>2</sub> Anodes for Electrochemical Water Treatment

Yi Zhang, Yang Yang, Shasha Yang, Estefanny Quispe-Cardenas, Michael R. Hoffmann

2021ACS ES&T Engineering46 citationsDOIOpen Access PDF

Abstract

Electrochemical oxidation can be used for decentralized wastewater treatment without the addition of chemicals. Antimony-doped tin oxide (Sb-SnO2: AT) provides a catalytic anode coating that is easily prepared at a relatively low cost. However, there is the potential of Sb leaching during use. To overcome this problem, a heterojunction anode is developed that uses an AT oxide layer as an ohmic contact and a nickel-doped AT oxide layer (NAT) with a substantially lower Sb content as an outer catalytic layer (NAT/AT). The two-layer NAT/AT anode has significantly longer operational lifetimes, lower Sb leaching potential, and higher activities for free radical generation and ozone production than either layer when used alone. Based on experimental results in combination with theory, an anodic ozone activation pathway at the acidic electrode/electrolyte interface is identified as a key •OH source coupled with direct •OH production via water electrolysis. The NAT/AT anode outperforms commercial anodes (e.g., boron-doped diamond and IrO2) for organic compound destruction and for microbial disinfection. The 1-log removal of carbamazepine (surface area-normalized first-order rate constant kCBZ,SA = 1.13 × 10–3 m/s) and 5-log inactivation of E. coli and MS2 virus are achieved within 60 s in synthetic electrolytes. Even though the electrochemical efficiency is lower in the case of latrine wastewater treatment, the energy consumption (e.g., 3.9–14.0 kWh/m3) is low compared to previously reported values.

Topics & Concepts

AnodeMaterials scienceOxideElectrochemistryElectrolysisTin oxideElectrolyteChemical engineeringInorganic chemistryElectrodeChemistryMetallurgyEngineeringPhysical chemistryAdvanced oxidation water treatmentAdvanced Photocatalysis TechniquesAdvanced battery technologies research