Variation in sorption of propiconazole with biochars: The effect of temperature, mineral, molecular structure, and nano-porosity

[Display omitted] •Surface polar groups mainly consisted of O-containing groups of minerals.•Pore-filling in aromatic C of biochar control nonlinear propiconazole sorption.•HTT or C contents of biochar didn’t necessarily control propiconazole sorption.•Minerals may exert certain influence on propico...

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Published in:Chemosphere (Oxford) 2016-01, Vol.142, p.56-63
Main Authors: Sun, Ke, Kang, Mingjie, Ro, Kyoung S., Libra, Judy A., Zhao, Ye, Xing, Baoshan
Format: Article
Language:English
Subjects:
Adsorption
Animals
Biochar
Charcoal - chemistry
Environmental Pollutants - chemistry
Environmental Pollutants - isolation & purification
Mineral
Minerals - chemistry
Nanopores
Nanoporosity
Propiconazole
Sorption
Surface composition
Temperature
Triazoles - chemistry
Triazoles - isolation & purification
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Summary:[Display omitted] •Surface polar groups mainly consisted of O-containing groups of minerals.•Pore-filling in aromatic C of biochar control nonlinear propiconazole sorption.•HTT or C contents of biochar didn’t necessarily control propiconazole sorption.•Minerals may exert certain influence on propiconazole sorption. Sorption behavior of propiconazole (PROPI) by plant-residue derived biochars (PLABs) and animal waste-derived biochars (ANIBs) obtained at three heating treatment temperatures (HTTs) (300, 450 and 600°C) (e.g., BCs300, BCs450, and BCs600) and their corresponding de-ashed BCs450 was investigated. PLABs belonged to high- or medium-C biochars and ANIBs were low-C biochars. Surface C concentrations of the tested biochars were generally higher than their corresponding bulk C. Surface polar groups were mainly composed of O-containing groups of minerals within biochars. The nonlinearity coefficients (n) of propiconazole (PROPI) sorption isotherms ranged from 0.23 to 0.64, which was significantly and negatively related to organic carbon (OC)–normalized CO2-surface area (CO2-SA/OC) of biochars. This correlation along with the positive relationship between CO2-SA/OC and aromaticity indicates that pore-filling in nanopores within aromatic C dominate nonlinear PROPI sorption. HTTs or C contents do not necessarily regulate PROPI sorption. Removal of minerals from BCs450 elevated PROPI sorption because minerals may exert certain influence on sorption via impacting spatial arrangement of polar groups and/or organic matter (OM)–mineral interactions. This study helps to better understand sorption behavior of PROPI to biochars and evaluate the potential role of biochar in water treatment systems.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2015.07.018