Saturated permeability and water retention capacity in biochar-methanotrophs-clay for new landfill cover system

Wenjing Sun , Gaoge Sun , Shuyun Zhang
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Abstract

A new landfill cover system, biochar-methanotrophs-clay (BMC) cover is recommended for reducing methane emissions at landfills. It also contributes to decreasing soil permeability and improving soil water retention in a long time, due to highly porous structure of biochar and the growth metabolism of methanotrophs. To determine the effects of biochar content, oxidation aging times and methane-filled days on hydraulic properties, a total of 60 groups of experiments were conducted. The saturated hydraulic conductivity (ksat) was obtained by flexible wall permeameter with controllable hydraulic head pressure. The results showed that the ksat of BMC increased with increasing biochar content and oxidation aging times, while decreased with adding methane-filled days. The soil-water characteristic curves (SWCCs) were obtained with soil suction measured by the filter paper method. The results indicated the water retention capacity of MBC reduced with increasing oxidation aging times but increased with adding methane-filled days. Detected by mercury intrusion porosimetry (MIP), fourier transform infrared spectroscopy (FTIR) and scanning electron microscope (SEM), the differences displayed the changes of pore structures and extracellular polymeric substances (EPS). The oxidation aging of biochar increased the volume of pores, resulting in the increased ksat and the decreased water retention capacity. However, the growing of methanotrophs decreased the volume of pores, resulting in the ksat decreased and the water retention capacity increased due to EPS. No matter how many times the oxidation aging process was experienced, the BMC with longer methane-filled days exhibited relatively lower ksat and better water retention capacity. This implied a more stable barrier capacity to reduce water infiltration in the long term. By combing a series of macro and micro experiments, this paper provides theoretical guidance for the application of biochar-methanotroph-clay mixture to landfill covers.

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新型垃圾填埋场覆盖系统中生物炭-甲烷-粘土的饱和渗透性和保水能力
为减少垃圾填埋场的甲烷排放,建议采用一种新的垃圾填埋场覆盖系统,即生物炭-甲烷营养土(BMC)覆盖系统。由于生物炭的高孔隙结构和甲烷养分菌的生长代谢,它还有助于降低土壤的渗透性和提高土壤的长期保水性。为了确定生物炭含量、氧化老化时间和甲烷填充天数对水力特性的影响,共进行了 60 组实验。饱和导水性(ksat)是通过可控水头压力下的柔性壁渗透仪获得的。结果表明,BMC 的 ksat 随生物炭含量和氧化老化时间的增加而增加,但随甲烷填充天数的增加而减少。通过滤纸法测量土壤吸力,获得了土壤水特征曲线(SWCC)。结果表明,随着氧化老化时间的增加,MBC 的保水能力降低,但随着甲烷填充天数的增加,保水能力提高。通过汞侵入孔隙测定法(MIP)、傅立叶变换红外光谱法(FTIR)和扫描电子显微镜(SEM)检测,差异显示了孔隙结构和胞外聚合物质(EPS)的变化。生物炭的氧化老化增加了孔隙体积,导致 ksat 增加和保水能力下降。然而,甲烷滋养菌的生长减少了孔隙体积,导致 ksat 下降,而 EPS 则增加了保水能力。无论经历多少次氧化老化过程,甲烷填充天数较长的 BMC 的 ksat 都相对较低,保水能力较强。这意味着在长期减少水渗入方面具有更稳定的阻隔能力。通过结合一系列宏观和微观实验,本文为生物炭-甲烷-粘土混合物在垃圾填埋场覆盖层中的应用提供了理论指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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