PNNL

Abstract

Electrocatalytic oxidation (ECO) is a promising method for generating molecular hydrogen (H2) while simultaneously treating the aqueous phase (AP) from hydrothermal liquefaction (HTL) of biomass-derived feedstocks such as algae, food waste, sludge, and wood. This study highlights the impact of HTL-AP composition on ECO performance, mainly activity, stability, and efficiency in a batch and flow electrolyzer. We demonstrated current efficiency (CE) for chemical oxygen demand (COD) removal ranges from 14% to 85% in the flow electrolyzer with electrode stability increasing from 20 to =2,800 h. Decreasing the applied potential enhances the CE. High ammonium content can accelerate deactivation, yet chloride ions appear to aid oxidation of organic compounds and enhanced anode stability. A preliminary energy and H2 balance for an HTL sewage sludge plant shows that the HTL-AP contains sufficient COD to produce all the H2 needs for bio-oil hydrotreating, with a 26% surplus available for other uses.