| Title | Burgeoning innovation and scalability activities for phosphorus recovery from wastewater treatment facilities |
|---|---|
| ID_Doc | 32468 |
| Authors | Al-Juboori, RA; Ahmed, FE; Khanzada, NK; Khatri, M; Al-shaeli, M; Ibrahim, Y; Hilal, N |
| Title | Burgeoning innovation and scalability activities for phosphorus recovery from wastewater treatment facilities |
| Year | 2024 |
| Published | |
| Abstract | Phosphorus has been described as life's bottleneck due to its finite source and indispensable role in sustaining living cell functionalities. The paradigm shift from recycling to linear phosphorus consumption that transpired after the Green Revolution brought about one of the most concerning recent environmental challengeseutrophication. Many recovery technologies have been developed to reinstate phosphorous recycling in sophisticated and safe ways. This study critically reviewed the current state of global phosphorous natural reserves and pollution. It also discussed forecasted consumption trends and how the recovery could assist in meeting the increasing phosphorous demands. The current phosphorous recovery processes were reviewed. A multi-criteria comparison of the technologies within their technology redness levels (TRLs) groups was carried out using the PROMETHEE ranking approach. The comparison criteria focused on efficiency, product quality, and energy and chemicals consumption. The processes with the highest preference scores in their respective TRL groups employed chemical leaching and struvite precipitation. This study also presents patent analyses of P recovery technologies over the past 8 years. These analyses showed that China is at the forefront of patent production, while Europe leads in commercialization. Biochar modification and electrode materials development dominate recent innovations in P recovery. |
Similar Articles
| ID | Score | Article |
|---|---|---|
27333
|
Zhu, FY; Cakmak, EK; Cetecioglu, Z Phosphorus recovery for circular Economy: Application potential of feasible resources and engineering processes in Europe(2023) | |
| 13982
|
Egle, L; Rechberger, H; Zessner, M Overview and description of technologies for recovering phosphorus from municipal wastewater(2015) | |
| 14641
|
Di Capua, F; de Sario, S; Ferraro, A; Petrella, A; Race, M; Pirozzi, F; Fratino, U; Spasiano, D Phosphorous removal and recovery from urban wastewater: Current practices and new directions(2022) | |
| 18304
|
Bianchini, A; Rossi, J An Integrated Industry-Based Methodology to Unlock Full-Scale Implementation of Phosphorus Recovery Technology(2020)Sustainability, 12.0, 24 | |
| 9739
|
Wang, ZX; Anand, D; He, Z Phosphorus Recovery from Whole Digestate through Electrochemical Leaching and Precipitation(2023)Environmental Science & Technology, 57.0, 27 | |
| 20388
|
Jama-Rodzenska, A; Bialowiec, A; Koziel, JA; Sowinski, J Waste to phosphorus: A transdisciplinary solution to P recovery from wastewater based on the TRIZ approach(2021) | |
| 9432
|
Lam, KL; Solon, K; Jia, MS; Volcke, EIP; van der Hoek, JP Life Cycle Environmental Impacts of Wastewater-Derived Phosphorus Products: An Agricultural End-User Perspective(2022)Environmental Science & Technology, 56.0, 14 | |
| 16966
|
Dell'Osbel, N; Colares, GS; de Oliveira, GA; de Souza, MP; Barbosa, CV; Machado, EL Bibliometric Analysis of Phosphorous Removal Through Constructed Wetlands(2020)Water Air And Soil Pollution, 231, 3 | |
| 2401
|
Kasprzyk, M; Czerwionka, K; Gajewska, M Waste materials assessment for phosphorus adsorption toward sustainable application in circular economy(2021) | |
| 4000
|
Guedes, P; Couto, N; Mateus, EP; Ribeiro, AB Phosphorus Recovery in Sewage Sludge by Electrokinetic Based Technologies: A Multivariate and Circular Economy View(2017)Waste And Biomass Valorization, 8, 5 |