Abstract
Bio-oils derived from biomass contain organic species and acids that can be corrosive to steel-based structural materials used for pipelines and storage tanks. It is, therefore, important to assess corrosivity of organic constituents in bio-oils and identify ferrous alloys with sufficient corrosion resistance. In this work, lactobionic acid, formic acid and catechol were selected for corrosive constituents in bio-oils and used to formulate simulated bio-oils where 4 ferrous alloys, including 2.25Cr-1Mo steel and type 410, 201 and 316 stainless steels, were tested by Electrochemical Impedance Spectroscopy (EIS). The corrosivity of each simulated bio-oils was assessed using R2, a charge transfer limiting resistance fitted from EIS spectra. Whie 2.25Cr-1Mo steel exhibited active corrosion with low R2 values, the stainless steels showed high R2 values associated with passive state. The values of R2, considered proportional to the stability of the passive film, appeared lower in lactobionic acid than the other simulated bio-oils for the stainless steels, suggesting that lactobionic acid could be more aggressive to passive film than the other constituents of bio-oils. The overall goal of this work is to use EIS to systematically study the impact of bio-oil constituents on corrosion of candidate structural materials for bio-oil production, transport, and storage, as well as provide feedback for potential optimization of bio-oil chemistries to reduce the risk of corrosion.
