Ammonia poses a threat to biodiversity in aquatic environments, having toxic effects on fish living in freshwater and seawater. In this work, we have designed a photoelectrochemical reactor and tested in a recirculating aquaculture system (RAS, Fig.1a). This technology exploits the UV-electrochlorine advanced oxidation process to improve water quality and fish welfare, performance and sustainability. The photoanode is prepared by anodization of a metal titanium mesh in a ethylene glycol, water and hydrofluoric acid electrolyte solution at 30 V for 6 h in order to obtain a self assembled titania nanotube arrays film (Fig.1b). The illuminated semiconductor film promotes the oxidation of chloride ions naturally present in fresh- (or sea-) water, to chlorine radical which is highly reactive and selective in ammonia oxidation yielding N2 or nitrate. Preliminary ammonia degradation tests were performed in 5∙mM KCl cotaining 100 ppm NH3 solutions at 4 V potential bias. A stable photocurrent up to 550 mA under UV- irradiation was obtained during the test. An almost full ammonia conversion was reached after 6 h-long test with a selectivity towards N2 and NO3- of 80% and 20%, respectively. The setup has been shown to be biocompatible in a real rainbow trout farming plant showing a lower nitrate accumulation in water with respect to a traditional bio-filter.
Innovative Photoelectrocatalytic filter for Recirculating Aquaculture Systems / L. Maistrello, S. Livolsi, A. Costa, E. Buoio, A. Di Giancamillo, G.L. Chiarello - In: Atti del XXVIII Congresso. 1[s.l] : Società chimica italiana, 2024. - pp. 338-339 (( Intervento presentato al 28. convegno Congresso Nazionale SCI 2024, Elements of future tenutosi a Milano nel 2024.
Innovative Photoelectrocatalytic filter for Recirculating Aquaculture Systems
L. Maistrello;S. Livolsi;A. Costa;E. Buoio;A. Di Giancamillo;G.L. Chiarello
2024
Abstract
Ammonia poses a threat to biodiversity in aquatic environments, having toxic effects on fish living in freshwater and seawater. In this work, we have designed a photoelectrochemical reactor and tested in a recirculating aquaculture system (RAS, Fig.1a). This technology exploits the UV-electrochlorine advanced oxidation process to improve water quality and fish welfare, performance and sustainability. The photoanode is prepared by anodization of a metal titanium mesh in a ethylene glycol, water and hydrofluoric acid electrolyte solution at 30 V for 6 h in order to obtain a self assembled titania nanotube arrays film (Fig.1b). The illuminated semiconductor film promotes the oxidation of chloride ions naturally present in fresh- (or sea-) water, to chlorine radical which is highly reactive and selective in ammonia oxidation yielding N2 or nitrate. Preliminary ammonia degradation tests were performed in 5∙mM KCl cotaining 100 ppm NH3 solutions at 4 V potential bias. A stable photocurrent up to 550 mA under UV- irradiation was obtained during the test. An almost full ammonia conversion was reached after 6 h-long test with a selectivity towards N2 and NO3- of 80% and 20%, respectively. The setup has been shown to be biocompatible in a real rainbow trout farming plant showing a lower nitrate accumulation in water with respect to a traditional bio-filter.
| File | Dimensione | Formato | |
|---|---|---|---|
|
XXVIII-Congresso-Nazionale-SCI2024-Book-of-Abstract-volume-1_compressed (2).pdf
accesso aperto
Descrizione: Book of abstract, SCI 2024 congress
Tipologia:
Publisher's version/PDF
Dimensione
9.35 MB
Formato
Adobe PDF
|
9.35 MB | Adobe PDF | Visualizza/Apri |
Pubblicazioni consigliate
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
