Engineered biochar-attapulgite clay composite: A novel slow-release phosphorus fertilizer

Authors

Harleen Kaur, The University of Newcastle, Australia
Gurwinder Singh, The University of Newcastle, Australia
Marjana Yeasmin, RMIT University
Kavitha Ramadass, The University of Newcastle, Australia
Puspamitra Panigrahi, Hindustan Institute of Technology and Science
Alan Larson, Michigan Technological UniversityFollow
Ranjit Pati, Michigan Technological UniversityFollow
Dane Lamb, RMIT University
Bo Zheng, The University of Adelaide
Ehsan Tavakkoli, The University of Adelaide
Lukas Van Zwieten, NSW Department of Primary Industries
Ajayan Vinu, The University of Newcastle, Australia

Document Type

Article

Publication Date

9-15-2025

Department

Department of Physics

Abstract

Sustainable agricultural practices are in high demand, and the development of innovative materials for slow nutrient release holds utmost importance. Phosphorus (P) stratification limits plant P availability in no-till farming systems. To address this, a nano composite-based P fertilizer to release nutrients in the root zone following surface soil application is constructed. The nanocomposite fertilizers (BAP-SRFs) were formed by a combination of different amounts of biochar (BC), attapulgite clay (ATP) and KH2PO4, followed by a high-temperature treatment (500 °C). XANES analysis revealed the enrichment of the surface with carbon (C), oxygen (O) and P-containing functional groups, and the bond formation of P with calcium (Ca) and magnesium (Mg) and organic C. Batch desorption and dynamic release experiments provided conclusive evidence that an interplay between ATP and P contents is crucial for the optimum delivery of P in both aqueous and soil media. The slowest release of P in water was achieved in BAP-SRF, which had a BC to ATP ratio of 2 and was loaded with 200 mg of KH2PO4. Pseudo-second-order kinetics presented the best fit for P release, demonstrating that the release mechanism of P is primarily based on diffusion. The visual diffusion of P in soil provides critical evidence of the slow-release nature of the BAP-SRFs as compared to commercial single super phosphate. The experimental findings were further corroborated by the first principles density functional theory calculations, which highlighted that BC and ATP make an excellent combination to interact with the KH2PO4 and slow down its release. The engineered nanocomposite P fertilizers developed here may provide a solution for the intractable issue of P stratification in no-till farming systems.

Publisher's Statement

© 2025 The Authors. Published by Elsevier B.V. Publisher’s version of record: https://doi.org/10.1016/j.cej.2025.165791

Publication Title

Chemical Engineering Journal

Recommended Citation

Kaur, H., Singh, G., Yeasmin, M., Ramadass, K., Panigrahi, P., Larson, A., Pati, R., Lamb, D., Zheng, B., Tavakkoli, E., Van Zwieten, L., & Vinu, A. (2025). Engineered biochar-attapulgite clay composite: A novel slow-release phosphorus fertilizer. Chemical Engineering Journal, 520. http://doi.org/10.1016/j.cej.2025.165791
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p2/1841

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Version

Publisher's PDF