Biochar-compost-based controlled-release nitrogen fertilizer intended for an active microbial community

Robiul Islam Rubel, Lin Wei, Salman Alanazi, Abdulkarim Aldekhail, Anne C.M. Cidreira, Xufei Yang, Sanjita Wasti, Samarthya Bhagia, Xianhui Zhao

Research output: Contribution to journalArticlepeer-review

Abstract

Nitrogen (N) fertilizers in agriculture suffer losses by volatilization of N to the air, surface runoff and leaching into the soil, resulting in low N use efficiency (NUE) ( 50%) and raising severe environmental pollutions. Controlled-release nitrogen fertilizers (CRNFs) can control the release of N nutrients to NUE in crop production. Different methods were used to develop new CRNFs. However, different CRNF technologies are still underdeveloped due to inadequate controlling on N releasing time and/or unsustainable diffusion. The study on the influences of CRNF processing parameters on microbial conditions are lacking when the CRNFs composed of various bio-ingredients such as biochar, composts, and biowaste. The complexity of processing methods, material biodegradability, and other physical properties make current CRNFs of questionable value in agricultural production. This research aims to develop a novel biochar-compost-based controlled-release urea fertilizer (BCRUF) to preserve microbial properties carried by the compost. The BCRUF was synthesized by pelletizing the 50:50 (dry, wt/wt) mixture of biochar and compost. BCRUF was loaded with urea and then spray-coated with polylactic acid (PLA). The releasing time of two types of BCRUFs, coated and uncoated with PLA, for 80% of N release in water was up to 6 h at three different temperatures (4, 23, and 40 °C), compared to conventional urea fertilizer and commercial environmentally smart N (ESN) fertilizer. The releasing time of coated BCRUF for 80% N release in soil was up to 192 h (8 days). Fourier-transform infrared spectroscopy (FTIR) analysis revealed that no new functional groups were found in the release solution, indicating no new chemical hazards generated. The differential scanning calorimetry (DSC) tests also verified that its thermal stability could be up to 160 °C. The microbe populations in the BCRUF pellets were reduced after the pelleting and drying processes in BCRUF fabrication, but a few bacteria can endure in the air-drying process. BCRUF pellets soaked in water for 4 days retained some bacteria. The BCRUF showed very promising characteristics to improve NUE and sustainability in agricultural production.

Original languageEnglish
Pages (from-to)326-343
Number of pages18
JournalFrontiers of Agricultural Science and Engineering
Volume11
Issue number2
DOIs
StatePublished - 2024

Funding

This research received funding supports from the South Dakota Governor\u2019s Office of Economic Development (POC2020-04), the USDA NIFA through the North Central Regional Sun Grant Center, and Hatch Projects (3AR652, 3AR689, and 3AH658) of the South Dakota Agricultural Experiment Station. UT-Battelle LLC partly authored this manuscript under contract DE-AC05-00OR22725 with DOE. The US Government retains, and the publisher acknowledges that the US Government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript or allow others to do so for US Government purposes. DOE will provide public access to these federally sponsored research results per the DOE Public Access Plan.

FundersFunder number
National Institute of Food and Agriculture
US Government
U.S. Department of Energy
North Central Regional Sun Grant Center3AR689, 3AH658, 3AR652
South Dakota Agricultural Experiment StationDE-AC05-00OR22725
South Dakota Governor's Office of Economic DevelopmentPOC2020-04

    Keywords

    • Soil microbial community
    • biochar
    • compost
    • controlled-release nitrogen fertilizer
    • polylactic acid
    • spray coating

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