Abstract

• Caproate was produced in a two-stage process. • In the first stage SCFAs were produced from three complex substrates. • In the second stage CO 2 + H 2 promoted the production of ethanol. • Caproate was produced from SCFAs and ethanol previously accumulated. • A CO 2 -enriched atmosphere improved the caproate production up to 6 g/L. This study describes a two-stage process for the valorization of organic wastes and CO 2 /H 2 off-gas for the production of short-chain fatty acids (SCFAs) and ethanol, as precursors for n -caproate formation. Three complex organic wastes with previously identified acetogenic members were used to inoculate batch reactors: 1) fibers and 2) leachates from a bagasse fermentation process, and 3) an anaerobic granular sludge from a reactor treating brewery effluents. In the first stage, the reactors loaded with a CO 2 /H 2 [25:75, v/v] gas mixture produced SCFAs at similar concentrations between 4,274 and 5,381 mg/L. In this stage, fiber reactors had the highest H 2 consumption. In the second stage, reactors consumed all available H 2 and accumulated solvents as well as low concentrations of n -caproate. In particular, sludge reactors produced 3,528 mg/L of solvents with more than 50% ethanol content, and leachate reactors produced 617 mg/L of n -caproate. By the end of the second stage, in a CO 2 -enriched atmosphere, leachate reactors produced 6,157 mg/L of n -caproate at the expenses of the SCFAs and solvents. Fiber and leachate microbiotas shared autotrophic members and SCFA-elongating bacteria while sludge microbiota differed in composition. This study demonstrated that the use of CO 2 /H 2 off-gas shifted the composition of SCFAs to a mixture with ethanol which promoted its condensation into n -caproate. A CO 2 -enriched atmosphere improved significantly the final production of n -caproate. The results of this study can be used to integrate the n -caproate production, and possibly other medium-chain fatty acids, with biorefinery schemes in which SCFAs and CO 2 /H 2 off-gases are produced.

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