首页|Effects of hydroxyapatite and modified biochar derived from Camellia oleifera fruit shell on soil Cd contamination and N2O emissions
Effects of hydroxyapatite and modified biochar derived from Camellia oleifera fruit shell on soil Cd contamination and N2O emissions
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NSTL
Elsevier
? 2021 Elsevier B.V.Heavy metal pollution and global climate change caused by increased greenhouse gas emissions are two important challenges to sustainable development. Various strategies have been implemented to mitigate both heavy metal pollution and global climate change, including the use of biochar obtained from biorefinery of agroforestry biowaste. This study was conducted to clarify how nitrous oxide (N2O) emission and soil cadmium (Cd) contamination respond to mitigation strategies, aiming to understand which strategy will be efficient in mitigating both N2O emissions and Cd contamination. Effects of three soil conditioners (biochar; modified biochar, MB; hydroxyapatite, HAP) and Cd on N2O emissions from acid soil of Camellia oleifera plantations with nitrogen, and microbial functional genes related to N2O productions were examined. The results showed that Cd was decreased by 73.4% and 64.9% by HAP in control and fertilized soil, respectively. HAP reduced both Cd and N2O emissions more efficient compare to MB and biochar, which strongly associated with increased pH. Soil N2O emissions from fertilized soil without Cd were reduced by 91.0%, 34.3% and 25.8% by HAP, MB and biochar, respectively. However, soil N2O emissions with Cd were reduced by 67.3% and 24.6% by HAP and MB, respectively, while they were increased by 56.7% by biochar. Cd inhibited N2O emissions, via decreasing abundance of ammonia-oxidizing archaea in fertilized soil. Thereby, MB should be considered in amelioration of Cd-contaminated common soil, while HAP could be used in highly acid Cd-contaminated soil, which largely increase soil pH and simultaneously mitigated N2O emissions.
Cd contaminationGlobal warmingHydroxyapatiteMicrobial functional geneModified biocharNitrous oxide
NSTL
Elsevier
