Application of Corn Stover Derived Pyrolyzed Hydrochars for Efficient Phosphorus Removal from Water: Influence of Pyrolysis Temperature

Authors

• Md.Arafat Ali, University of Buffalo
• Cadianne Chambers, Florida Tech
• M.Toufiq Reza, Florida Tech
• Nirupam Aich, University of Buffalo and University of Nebraska-LincolnFollow

ORCID IDs

Ali https://orcid.org/0000-0002-5091-4893

Chambers https://orcid.org/0000-0002-6533-1076

 Aich https://orcid.org/0000-0003-1896-8127

Document Type

Article

Date of this Version

2024

Citation

Chemical Engineering Journal Advances (2024) 18: 100613

doi: 10.1016/j.ceja.2024.100613

Comments

Open access

License: CC BY-NC 4.0

Abstract

Excessive phosphorus load to surface water is undesirable since it can cause eutrophication. In this study, three different pyrolyzed hydrochars from corn stover were synthesized by applying hydrothermal carbonization (HTC) at 260 °C and then eventual pyrolysis at 400°, 600°, and 800 °C, respectively, and finally were used for phosphorus removal from aqueous solution. By linking the physicochemical properties of these pyrolyzed hydrochars investigated here, we tried to comprehend the effect of HTC and pyrolysis temperature on the hydrochar structure and phosphorus adsorption. Results show that high pyrolysis temperatures (600 °C and 800 °C) enhanced the hydrochar's phosphorus adsorption compared to low pyrolysis temperature (400 °C). HTC260P800 type hydrochar showed a fast phosphorus adsorption kinetics, while the HTC260P600 showed an overall high adsorption capacity, with the maximum phosphate adsorption capacity of 5090 mg/kg calculated using isotherm model. Three different adsorption isotherm models (Langmuir, Fruendlich, and Redlich-Peterson) were used to fit the isotherm data; among them, the Redlich-Peterson isotherm model fit the data best for all three hydrochars. pH was found to be a critical factor in terms of phosphorus removal, and the optimum pH was found to be 5, probably due to the enhanced electrostatic interaction between positively charged hydrochar and negatively charged phosphate ions. The desorption experiment showed that a small fraction of the adsorbed phosphate (15.6 % to 24.4 %) was released from the spent hydrochar samples, which might be due to the strong attachment of phosphate ions to the sorption sites. Reusing the spent pyrolyzed hydrochar showed lower phosphate adsorption capacity than the fresh ones, ranging from 423 mg/kg to 903 mg/kg.