Adsorption of phosphorus in water by metal-modified large-size biochar: Realizing the recovery and recycling of phosphorus

Biochar finds extensive use in adsorbing phosphorus (P) from wastewater abundant in P content. Most biochars carry negative surface charges, causing electrostatic repulsion towards anions. However, as P commonly exists as anions in water, the P adsorption capacity of biochar remains limited. Moreove...

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Bibliographic Details
Published in:Sustainable chemistry and pharmacy 2023-12, Vol.36, p.101279, Article 101279
Main Authors: Hu, Ziwan, Wu, Rongtai, Pang, Ximing, Yu, Chenghao, Jian, Xiumei
Format: Article
Language:English
Subjects:
Large-size
Modification
Phosphorous adsorption
Phosphorus cycle
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Summary:Biochar finds extensive use in adsorbing phosphorus (P) from wastewater abundant in P content. Most biochars carry negative surface charges, causing electrostatic repulsion towards anions. However, as P commonly exists as anions in water, the P adsorption capacity of biochar remains limited. Moreover, conventional biochar used for P adsorption presents challenges in recycling due to its small particle size. This study presented a novel approach wherein metal-modified large-size (1–2 mm) walnut shell biochars were created using Fe, Mg, and Ca additives at varying ratios. This innovation aims to enhance P adsorption capacity and recyclability. Experimental findings revealed that unmodified biochar (BC) exhibited minimal P adsorption capacity (0.34 mg/g), while all metal-modified biochars (MBCs) demonstrated elevated P adsorption capabilities (1.06–25.60 mg/g). Among the distinct MBCs, Ca-MBCs displayed the highest P adsorption capacity (25.60 mg/g), trailed by Mg-MBCs (23.58 mg/g) and Fe-MBCs (5.99 mg/g). Furthermore, both isotherm and kinetic adsorption analyses suggested that the P adsorption mechanism for MBCs predominantly involves chemical adsorption. However, desorption studies post-adsorption indicated suboptimal desorption efficiencies for P (19.16–26.07%) in MBCs, posing challenges for their application as fertilizers. Therefore, it is essential to enhance simultaneous P adsorption and desorption capabilities of biochar. [Display omitted] •Developed metal-modified large-size adsorbents for P adsorption in wastewater.•Among MBCs modified by Fe, Mg, and Ca, Ca-MBCs had the highest P adsorption capacity.•The maximum P adsorption capacity of Ca-modified biochar was 25.60 mg/g.•Adsorbed large-size Ca-MBCs can recycle P to realize the P cycle.•Ca-modified biochar adsorbed P mainly through coprecipitation to form hydroxyapatite.
ISSN:2352-5541
2352-5541
DOI:10.1016/j.scp.2023.101279