1 research outputs found
Distinct Mechanisms on Accelerating Electron Transfer to Facilitate Two-Stage Anaerobic Digestion Modulated by Various Microalgae Biochar
Microalgae-derived biochar are promising candidates to
accelerate
electron transfer during anaerobic digestion (AD) due to inherent
advantages, but the mechanisms are unclear since they are highly related
to microalgae species. In this work, distinct electron transfer mechanisms
modulated by biochar derived from Scenedesmus sp.
(SBC) and Chlorella sp. (CBC) were investigated during
two-stage AD. Overall, adding biochar enhanced direct interspecies
electron transfer (DIET) by increasing the relative abundance of related
microorganisms like Firmicutes and Methanosaeta. Furthermore, SBC showed a foamy honeycomb structure with abundant
functional groups, a rough surface, and irregular holes, which provided
habitats for microorganism colonization and acted as an electron conductor
for facilitating conductive material-mediated DIET (i.e., cDIET).
Meanwhile, CBC showed a closed spherical granule structure having
a smooth surface and low porosity, leading to stack of microorganisms
on the biochar surface and causing bioelectrically triggered DIET
(i.e., bDIET) via upregulated secretion of Flavins and C-type cytochromes. Results indicate that the electron transfer
rate via bDIET was one order of magnitude higher than that via cDIET,
resulting in a 53.9% increase on H2 yield and a 9.1% increase
on CH4 yield in the CBC group compared to SBC group. These
findings can enrich knowledge gaps of electron transfer mechanisms
modulated by microalgae biochar and may inspire more efficient AD
processes