Co-capture and resource recovery of ammonia and carbon dioxide in microbial electrolysis system with an assisted carbon capacitor chamber

Human activities lead to the excessive input of carbon and nitrogen elements into the water and atmosphere. The recovery and recycling of carbon and nitrogen have been gaining increasing attention. The microbial electrolysis cell (MEC) is anticipated to simultaneously recover nitrogen from wastewate...

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Bibliographic Details
Published in:Journal of cleaner production 2024-09, Vol.470, p.143337, Article 143337
Main Authors: Liu, Shujuan, Ding, Guofang, Hao, Jianxin, Liu, Pengcheng, Qin, Wenyong, Yu, Yanling, Han, Yu, Huang, Jianjun, He, Weihua
Format: Article
Language:English
Subjects:
absorption
adsorption
alkalinity
ammonia
ammonium nitrogen
anodes
bicarbonates
capacitors
Carbon capture and storage
carbon dioxide
carbon sequestration
carbonates
cathodes
electrolysis
energy
heat
High ammonia sewage
humans
inorganic carbon
liquid fertilizers
Microbial electrochemical system
microbial electrolysis cells
nitrogen
nitrogen fertilizers
Resources recovery
sewage
slags
Waste-heat utilization
wastewater
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Summary:Human activities lead to the excessive input of carbon and nitrogen elements into the water and atmosphere. The recovery and recycling of carbon and nitrogen have been gaining increasing attention. The microbial electrolysis cell (MEC) is anticipated to simultaneously recover nitrogen from wastewater and capture carbon from the atmosphere. In this study, a process for carbon and nitrogen co-capture, utilization, and storage centered on MEC (MEC-CNCUS) was proposed to reduce energy consumption and achieve carbon and nitrogen resource recovery and recycling. A three-chamber MEC system was developed, where ammonia nitrogen from sewage migrated across the membrane to the cathode chamber, and bicarbonate from the absorption chamber was simultaneously captured at the cathode driven by alkalinity gradients. The NH3 and CO2 released from the carbon-nitrogen co-absorption solution upon heating were fixed by CaCl2 slag to produce nitrogen fertilizer and nanometer CaCO3 products. With the optimal replacement frequency (12 h−1) and concentration (70 mmol L−1) of the CO2 adsorption solution, 55.1 ± 0.25% of ammonia nitrogen in the anode migrated to the cathode, and the inorganic carbon content of the catholyte increased by 31.54%. Following heating, the ammonia nitrogen was almost entirely transferred to liquid fertilizer, the CO2 recovery rate reached 54.6 ± 0.41%, and cubic nano-calcium carbonate product with good dispersion was obtained. The MEC-CNCUS system offers a potential technical approach for simultaneously achieving wastewater energy utilization, ammonia recovery, and carbon sequestration. [Display omitted] •The MEC-CNCUS system realized co-capture and recovery of carbon and nitrogen.•Providing potential idea for NH4+ and CO2 co-capture and waste-heat utilization.•47.5% ammonia and 54.6% carbon recovery were achieved.•Ammonia fertilizer and nano calcium carbonate products were obtained.
ISSN:0959-6526
DOI:10.1016/j.jclepro.2024.143337