Self-Powered Bioelectrochemical Nutrient Recovery for Fertilizer Generation from Human Urine

Nutrient recovery from source-separated human urine has been identified by many as a viable avenue towards the circular economy of nutrients. Moreover, untreated (and partially treated) urine is the main anthropogenic route of environmental discharge of nutrients, most concerning for nitrogen, whose...

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Bibliographic Details
Published in:Sustainability 2019-10, Vol.11 (19), p.5490
Main Authors: Freguia, Stefano, Logrieco, Maddalena, Monetti, Juliette, Ledezma, Pablo, Virdis, Bernardino, Tsujimura, Seiya
Format: Article
Language:English
Subjects:
Ammonia
Anthropogenic factors
Biochemical fuel cells
Biofilms
Calcium
Carbon
Catalysts
Chemical oxygen demand
Economic conditions
Electricity
Electrochemistry
Electrodes
Energy consumption
Fertilizers
Fuel cells
Fuel technology
Graphite
Heavy metals
Human wastes
Magnesium
Membranes
Micronutrients
Microorganisms
Nitrogen
Nutrients
Organic chemistry
Plant growth
Process controls
Sustainability
Trace metals
Urine
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Summary:Nutrient recovery from source-separated human urine has been identified by many as a viable avenue towards the circular economy of nutrients. Moreover, untreated (and partially treated) urine is the main anthropogenic route of environmental discharge of nutrients, most concerning for nitrogen, whose release has exceeded the planet’s own self-healing capacity. Urine contains all key macronutrients (N, P, and K) and micronutrients (S, Ca, Mg, and trace metals) needed for plant growth and is, therefore, an excellent fertilizer. However, direct reuse is not recommended in modern society due to the presence of active organic molecules and heavy metals in urine. Many systems have been proposed and tested for nutrient recovery from urine, but none so far has reached technological maturity due to usually high power or chemical requirements or the need for advanced process controls. This work is the proof of concept for the world’s first nutrient recovery system that powers itself and does not require any chemicals or process controls. This is a variation of the previously proposed microbial electrochemical Ugold process, where a novel air cathode catalyst active in urine conditions (pH 9, high ammonia) enables in situ generation of electricity in a microbial fuel cell setup, and the simultaneous harvesting of such electricity for the electrodialytic concentration of ionic nutrients into a product stream, which is free of heavy metals. The system was able to sustain electrical current densities around 3 A m–2 for over two months while simultaneously upconcentrating N and K by a factor of 1.5–1.7.
ISSN:2071-1050
2071-1050
DOI:10.3390/su11195490