Journal
ENVIRONMENTAL SCIENCE-PROCESSES & IMPACTS
Volume 23, Issue 11, Pages 1747-1758Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/d1em00247c
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Funding
- National Natural Science Foundation of China [21906010]
- State Environmental Protection Key Laboratory of Synergetic Control and Joint Remediation for Soil & Water Pollution [GHBK-2020-013]
- State Key Laboratory of Geohazard Prevention and Geoenvironment Protection Independent Research Project [SKLGP2019Z008]
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The study showed that Bio-CaCO3 can improve the stability of biochar at high temperatures, and the mechanism by which it enhances stability was explored in the research.
Biochar stability is a key factor affecting the efficiency of soil carbon sequestration. Mineral calcium carbonate (M-CaCO3) can enhance the stability of biochar, and the mechanism has been extensively studied; however, similar studies on biological calcium carbonate (Bio-CaCO3), another natural form of calcium carbonate, are lacking. In this work, Bio-CaCO3 was used as an additive to explore the mechanism by which it enhances the stability of biochar. The results showed that Bio-CaCO3 improved the stability of biochar at pyrolysis temperatures ranging from 250 to 700 degrees C, and the enhancement effects increased upon increasing the pyrolysis temperature. The enhancement effects of M-CaCO3 were better at lower temperatures (250 and 400 degrees C) while Bio-CaCO3 was better at higher temperatures (550 and 700 degrees C). Mechanistic studies showed that the enhanced stability of Bio-CaCO3 at 250 degrees C was due to the fact that the inorganic component in Bio-CaCO3 promoted the deoxidation of the carbon matrix and the aromatization of aliphatic carbon at 400 degrees C. The reasons for the increased stability using Bio-CaCO3 at high temperatures included two mechanisms. One is that the inorganic components in Bio-CaCO3 promoted the aromatization of the carbon matrix. The other is that the unique organic nitrogen-containing functional groups in Bio-CaCO3 underwent dimerization and cyclization with the organic carbon components in biomass to form a more stable pyridinic-N structure. This work provides novel ideas for enhancing biochar stability using Bio-CaCO3.
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