将合成气发酵和微生物电合成集成到一个单一的工艺单元中。
Syngas fermentation and microbial electrosynthesis integration as a single process unit.
机构信息
Department of Process, Energy and Environmental Technology, University of South-Eastern Norway, Norway.
Department of Electrical Engineering, Information Technology and Cybernetics, University of South-Eastern Norway.
出版信息
Bioresour Technol. 2022 Jul;356:127314. doi: 10.1016/j.biortech.2022.127314. Epub 2022 May 14.
Industrially relevant syngas (15 % CO, 15% H, 20% N in 50% CO) fermentation and microbial electrosynthesis were integrated as a single process unit in open and closed-circuit modes. This study examined the impact of electrochemical reducing power from -50 to -400 mV on the acetic acid synthesis and CO inhibition on fermentation. -150 mV vs. Ag/AgCl (3.0 NaCl) was identified as the lowest benchmark potential for improved acetic acid synthesis rate (0.263 mmol Lh), which is 15-fold higher than the open circuit mode's rate. No significant inhibition by CO in the fermentation was observed, while 60% of the gas was consumed. Anodic potential above 2.0 V substantially lowered the product formation. Superseding the fermentation medium with fresh inoculum through a fed-batch operation helped lower the anodic potential.
工业相关的合成气(15% CO、15% H、20% N 在 50% CO 中)发酵和微生物电合成被整合为一个单一的工艺单元,采用开环和闭环模式。本研究考察了电化学还原力从-50 至-400 mV 对乙酸合成和 CO 抑制发酵的影响。与 Ag/AgCl(3.0 NaCl)相比,-150 mV 被确定为提高乙酸合成速率(0.263 mmol Lh)的最低基准电位,这比开环模式的速率高 15 倍。发酵过程中未观察到 CO 的显著抑制,而 60%的气体被消耗。阳极电位高于 2.0 V 会大大降低产物的形成。通过补料分批操作用新鲜接种物取代发酵培养基有助于降低阳极电位。
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