Corrosion of UNS N06625 under Batch-Mode Biomass Supercritical Water Gasification (SCWG) of Lignin

Supercritical water gasification (SCWG) is a thermochemical conversion technology developed to transform various feedstocks, such as raw forest biomass materials, crude bio-oils and bio-wastes, into syngas (a combination of CO and H₂) for clean energy production. Despite the intensive research efforts that have been applied on the development of SCWG technology, the optimal SCWG operating parameters (temperature, pressure, and biomass/water ratio, etc.) are not well defined because of the complexity of feedstock types and conversion reactor configurations (batch or continuous mode). Moreover, little information is available to determine which alloys are suitable for the reactor construction in a long-term safe and cost-effective manner. This study investigated the corrosion of UNS N06625 under the catalytic SCWG conversion of lignin using standard high temperature autoclave testing methodology and XRD characterization of the formed corrosion products. It was found that the addition of NaOH catalyst resulted in a remarkable increase in H₂ production. After 12 cycle exposures to the catalytic SCWG environment, the corrosion layer formed on the alloy was composed of Cr₂O₃ and Ni₃S₂. Surprisingly, the addition of NaOH led to a positive weight change instead of weight loss as that occurred in non-catalytic SCWG processes. Further works, such as accurate weight loss measurements and SEM/FIB/TEM characterizations of corrosion layer, are needed to advance the understanding of how the alloy corroded under the catalytic SCWG of lignin.