期刊文献+

Biochar insights from laboratory incubations monitoring O_(2) consumption and CO_(2) production

原文传递
导出
摘要 Biochar has been touted as a long-term carbon sequestration tool.However,there are no studies evaluating biochar’s effect on oxygen(O_(2))consumption as a measure of the microbial respiration response to biochar.To gain insight into this aspect,we evaluated O_(2) consumption rates to test the hypothesis that biochar is an efficient agent for carbon dioxide(CO_(2))sequestration in soils.Four different biochar types and one activated charcoal were incubated alone and associated with three different soils for approximately 2 months in laboratory incubations.Headspace concentration of CO_(2) and O_(2) was periodically quantified.The data presented here confirm that the CO_(2) production following biochar’s addition to soils results in a process that is correlated to oxygen consumption.However,this overall stimulation is not clearly related to biochar type.Activated carbon resulted in the highest statistically significant stimulation of activity,despite it possessing the lowest quantity of volatile carbon and mineral nutrient sources.Taking into consideration our results,we conclude that using biochar does achieve total carbon sequestration.However,the amount of available soil organic carbon following soil incorporation appears to be reduced following biochar addition and its long-term implication on this mineralizable soil organic carbon pool does deserve more research attention.
出处 《Biochar》 2019年第3期249-258,共10页 生物炭(英文)
  • 相关文献

参考文献1

二级参考文献35

  • 1Accardi-Dey A, Gschwend P M, 2003. Reinterpreting literature sorption data considering both absorption into organic carbon and adsorption onto black carbon. Environmental Science & Technology, 37(1): 99-106.
  • 2Ahmad R, Kookana R S, Alston A M, Skjemstad J O, 2001. The nature of soil organic matter affects sorption of pesticides: 1. Relationships with carbon chemistry as determined by ^13C CPMAS NMR spectroscopy. Environmental Science & Technology, 35(5): 878-884.
  • 3Alexander M, 1995. How toxic are toxic chemicals in soil? Environmental Science & Technology, 29(11): 2713-2717.
  • 4Allen-King R M, Grathwohl P, Ball W P, 2002. New modeling paradigms for the sorption of hydrophobic organic chemicals to heterogeneous carbonaceous matter in soils, sediments and rocks. Advances in Water Resources, 25(8- 12): 985-1016.
  • 5Cao X D, Ma L N, Gao B, Harris W, 2009. Dairy-manure derived biocha effectively sorbs lead and atriazine. Environmental Science & Technology, 43(9): 3285-3291.
  • 6Chen B L, Zhou D D, Zhu L Z, 2008. Transitional adsorption and partition of nonpolar and polar aromatic contaminants by biochars of pine needles with different pyrolytic temperatures. Environmental Science & Technology, 42(14): 5137-5143.
  • 7Chiou C T, Daniel E K, David W R, 2000. Sorption of selected organic compounds from water to a peat soil and its humicacid and humin fractions: Potential sources of the sorption nonlinearity. Environmental Science & Technology, 34(7): 1254-1258.
  • 8Crutzen P J, Andreae M O, 1990. Biomass burning in the tropics: Impact on atmospheric chemistry and biogeochemical cycles. Science, 250(4988): 1669-1678.
  • 9EFSA (European Food Safety Authority), 2006. Conclusion regarding the peer review of the pesticide risk assessment of the active substance: pyrimethanil. Summary of the EFSA Scientific Report, 61: 1-5.
  • 10Ghosh U, Gillette I S, Luthy R G, Zare R N, 2000. Microscale location, characterization, and association of polycyclic aromatic hydrocarbons on harbor sediment particles. Environmental Science & Technology, 34(9): 1729-1736.

共引文献18

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部