Abstract
The bioelectrochemical methane production from acetate as a non-fermentable substrate, glucose as a fermentable substrate, and their mixture were investigated in an anaerobic sequential batch reactor exposed to an electric field. The electric field enriched the bulk solution with exoelectrogenic bacteria (EEB) and electrotrophic methanogenic archaea, and promoted direct interspecies electron transfer (DIET) for methane production. However, bioelectrochemical methane production was dependent on the substrate characteristics. For acetate as the substrate, the main electron transfer pathway for methane production was DIET, which significantly improved methane yield up to 305.1 mL/g chemical oxygen demand removed (CODr), 77.3% higher than that in control without the electric field. For glucose, substrate competition between EEB and fermenting bacteria reduced the contribution of DIET to methane production, resulting in the methane yield of 288.0 mL/g CODr, slightly lower than that of acetate. In the mixture of acetate and glucose, the contribution of DIET to methane production was less than that of the single substrate, acetate or glucose, due to the increase in the electron equivalent for microbial growth. The findings provide a better understanding of electron transfer pathways, biomass growth, and electron transfer losses depending on the properties of substrates in bioelectrochemical methane production.
Highlights
Anaerobic digestion is a sustainable bioprocess that stabilizes organic waste, while recovering methane as a useful by-product
Acidogenic bacteria ferment the monomers to intermediates, including acetate, hydrogen, and formic acid, and methanogenic archaea convert the intermediates to methane [1,2,3]
Anaerobic digestion is a kind of indirect interspecies electron transfer (IIET) process, in which intermediates shuttle electrons between acidogenic bacteria and methanogenic archaea [2,3,4]
Summary
Anaerobic digestion is a sustainable bioprocess that stabilizes organic waste, while recovering methane as a useful by-product. Acidogenic bacteria ferment the monomers to intermediates, including acetate, hydrogen, and formic acid, and methanogenic archaea convert the intermediates to methane [1,2,3]. Anaerobic digestion is a kind of indirect interspecies electron transfer (IIET) process, in which intermediates shuttle electrons between acidogenic bacteria and methanogenic archaea [2,3,4]. The IIET involved in methane production is a series of multi-step enzymatic reactions with significant electron losses [1,4,5,6]. The enzymatic reactions cannot fully transfer electrons thermodynamically from the substrate to methane [4,6]. The methane yield that can be obtained from organic matter does not reach its theoretical value of
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