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As a new functional material, biochar was usually prepared from biomass and solid wastes such as agricultural and forestry waste, sludge, livestock, and poultry manure. The wide application of biochar is due to its abilities to remove pollutants, remediate contaminated soil, and reduce greenhouse gas emissions. In this paper, the influence of preparation methods, process parameters, and modification methods on the physicochemical properties of biochar were discussed, as well as the mechanisms of biochar in the remediation of soil pollution. The biochar applications in soil remediation in the past years were summarized, such as the removal of heavy metals and persistent organic pollutants (POPs), and the improvement of soil quality. Finally, the potential risks of biochar application and the future research directions were analyzed.
Xue Yang; Shiqiu Zhang; Meiting Ju; Le Liu. Preparation and Modification of Biochar Materials and their Application in Soil Remediation. Applied Sciences 2019, 9, 1365 .
AMA StyleXue Yang, Shiqiu Zhang, Meiting Ju, Le Liu. Preparation and Modification of Biochar Materials and their Application in Soil Remediation. Applied Sciences. 2019; 9 (7):1365.
Chicago/Turabian StyleXue Yang; Shiqiu Zhang; Meiting Ju; Le Liu. 2019. "Preparation and Modification of Biochar Materials and their Application in Soil Remediation." Applied Sciences 9, no. 7: 1365.
Bisphenol S (BPs) has been found in a variety of common consumer products surrounding human living, despite the fact that it could damage the human digestive system and genital system. In China, straw-returning to the field is a common soil improvement technology used to increase the concentration of dissolved organic matter (DOM), which plays an important role in the natural environment as a microreactor of contaminants. Additionally, the biochar obtained by the straw is an effective soil conditioner. DOM is a key influencing factor when biochar is employed as the conditioner of BPs contaminated soil. However, the BPs adsorption behavior on the Ferralsol affected by DOM and biochar is also unclear. Hence, DOM was prepared and the effect of DOM on the BPs adsorption behavior on soil and biochar modified soil was investigated. DOM was characterized by Elemental analysis, Fourier transforming infrared spectra (FT-IR), and three-dimensional excitation-emission matrix spectra (3D-EEM). The results of the adsorption experiments indicated that both biochar and DOM could improve the BPs adsorption capacity in Ferralsol, while DOM suppressed the BPs adsorption capacity of biochar modified soil, indicating that DOM and BPs could not be applied at the same time for BPs adsorption.
Shiqiu Zhang; Xue Yang; Le Liu; Kui Zheng; Meiting Ju; Jinpeng Liu. Bisphenol S Adsorption Behavior on Ferralsol and Biochar Modified Soil with Dissolved Organic Matter. International Journal of Environmental Research and Public Health 2019, 16, 764 .
AMA StyleShiqiu Zhang, Xue Yang, Le Liu, Kui Zheng, Meiting Ju, Jinpeng Liu. Bisphenol S Adsorption Behavior on Ferralsol and Biochar Modified Soil with Dissolved Organic Matter. International Journal of Environmental Research and Public Health. 2019; 16 (5):764.
Chicago/Turabian StyleShiqiu Zhang; Xue Yang; Le Liu; Kui Zheng; Meiting Ju; Jinpeng Liu. 2019. "Bisphenol S Adsorption Behavior on Ferralsol and Biochar Modified Soil with Dissolved Organic Matter." International Journal of Environmental Research and Public Health 16, no. 5: 764.
The flotation behaviors of perovskite, titanaugite, and magnesium aluminate spinel (MA-spinel), using octyl hydroxamic acid (OHA) as the collector, were investigated using microflotation experiments, zeta-potential measurements, Fourier transform infrared (FT-IR) analyses, X-ray photoelectron spectroscopy (XPS) analyses, and flotation experiments on artificially mixed minerals. The microflotation experiments show that the floatability of perovskite is clearly better than titanaugite and MA-spinel at around pH 5.5, while titanaugite possesses certain floatability at pH 6.0–6.5, and MA-spinel displays good floatability at pH > 8.0. The results of the FT-IR and XPS analyses show that OHA mainly interacts with Ti, resulting in perovskite flotation, and that the Al on titanaugite, as well as the Mg and Al on the MA-spinel surface, chemically react with OHA under acidic conditions. However, OHA mainly reacts with the Ti and Ca on the perovskite surface, Ca and Mg on the titanaugite surface, and Mg and Al on the MA-spinel surface under alkaline conditions. The results of the artificially mixed mineral flotation experiment show that the concentrate of TiO2 grade increased from 19.73% to 30.18% at pH 5.4, which indicates that a weakly acidic solution is the appropriate condition for the flotation separation of perovskite from titanaugite and MA-spinel. The results of the modified slag flotation experiments show that the TiO2 grade of concentrate increased from 18.13% to 23.88% at pH 5.4, through the open circuit test of “one roughing and one cleaning”. OHA displays selectivity toward perovskite in the modified slag flotation, but the consumption of H2SO4 is very high. The CaSO4 precipitate covered on the mineral surfaces results in poor TiO2 grade and recovery.
Weiqing Wang; Yangge Zhu; Shiqiu Zhang; Jie Deng; Yang Huang; Wu Yan. Flotation Behaviors of Perovskite, Titanaugite, and Magnesium Aluminate Spinel Using Octyl Hydroxamic Acid as the Collector. Minerals 2017, 7, 134 .
AMA StyleWeiqing Wang, Yangge Zhu, Shiqiu Zhang, Jie Deng, Yang Huang, Wu Yan. Flotation Behaviors of Perovskite, Titanaugite, and Magnesium Aluminate Spinel Using Octyl Hydroxamic Acid as the Collector. Minerals. 2017; 7 (8):134.
Chicago/Turabian StyleWeiqing Wang; Yangge Zhu; Shiqiu Zhang; Jie Deng; Yang Huang; Wu Yan. 2017. "Flotation Behaviors of Perovskite, Titanaugite, and Magnesium Aluminate Spinel Using Octyl Hydroxamic Acid as the Collector." Minerals 7, no. 8: 134.