Accessing biochar's porosity using a new low field NMR approach and its impacts on the retention of highly mobile herbicides.

Agrowaste biochars [sugarcane straw (SS), rice husk (RH), poultry manure (PM), and sawdust (SW)] were synthesized at different pyrolysis temperatures (350, 450, 550, and 650 °C) to evaluate their potential to retain highly mobile herbicides, such as hexazinone and tebuthiuron that often contaminate water resources around sugarcane plantations. A new low field nuclear magnetic resonance approach based on decay due to diffusion in internal magnetic field (NMR-DDIF) was successfully used to determine biochar's porosity and specific surface area (SSA) to clear the findings of this work. SSA of pores with diameters >5.0 μm increased with pyrolysis temperatures and seemed to dictate biochar's retention, which was >70% of the applied amounts at 650 °C. These macropores appear to act as main arteries for herbicide intra-particle diffusion into smaller pores, thus enhancing herbicides retention. Biochar granulometry had little, but herbicide aging had a significant effect on sorption, mainly of tebuthiuron. However, soils amended with 10,000 kg ha−1 of the biochars showed low sorption potential. Therefore, higher than usual biochar rates or proper incorporation strategies, i.e., surface incorporation, will be needed to remediate areas contaminated with these highly mobile herbicides, thus precluding their leaching to groundwaters. [Display omitted] • A novel low field NMR-DDIF was successfully used to access biochar's porosity. • Biochar's macropores and sorption enhanced with pyrolysis temperatures. • SSA of pores with diameters >5.0 μm seemed to dictate biochar sorption. • Herbicide aging enhanced sorption, but biochar granulometry did not. • High biochar rate or proper incorporation is needed to retain mobile herbicides. [ABSTRACT FROM AUTHOR]