研究入侵性杂草水葫芦合成的土壤-生物炭复合材料的开裂和水分可用性。

Investigation of cracking and water availability of soil-biochar composite synthesized from invasive weed water hyacinth.

机构信息

Department of Civil Engineering, Indian Institute of Technology Guwahati, India.

Department of Civil and Environmental Engineering, Shantou University, China.

出版信息

Bioresour Technol. 2018 Sep;263:665-677. doi: 10.1016/j.biortech.2018.05.011. Epub 2018 May 3.

DOI:10.1016/j.biortech.2018.05.011

PMID:29793826

Abstract

Water hyacinth (WH), is one of the world's most intractable and invasive weed species. Recent studies explored the efficacy of this species as a biochar (BC) in improving soil fertility and metal adsorption. However, the soil water retention (SWR) property and crack potential of soil-WH biochar composite has still not been studied. The major objective of this study is to investigate the SWR property and corresponding crack intensity factor (CIF) for compacted soil-WH BC composites. Soil-WH BC composites at five percentages (0, 2, 5, 10 and 15) was compacted and soil parameters such as suction (ψ), water content and CIF were simultaneously monitored for 63 days (including 9 drying-wetting cycles). Results showed that soil-WH BC composite at all percentages retains more water (max. 19% and min. 6.53%) than bare soil at both saturated and drought conditions. Gradual inclusion of WH BC to soil decreases the CIF potential from 7% to 2.8%.

摘要

水葫芦（WH）是世界上最顽固和最具入侵性的杂草物种之一。最近的研究探索了该物种作为生物炭（BC）在提高土壤肥力和金属吸附方面的功效。然而，土壤-WH 生物炭复合材料的土壤保水（SWR）性能和裂缝潜在性仍未得到研究。本研究的主要目的是研究压实土壤-WH BC 复合材料的 SWR 性能和相应的裂缝强度因子（CIF）。将 5 个百分比（0、2、5、10 和 15）的土壤-WH BC 复合材料压实，并同时监测土壤参数，如吸力（ψ）、含水量和 CIF，共 63 天（包括 9 个干湿循环）。结果表明，与饱和和干旱条件下的裸土相比，所有百分比的土壤-WH BC 复合材料保留了更多的水（最大 19%，最小 6.53%）。逐渐将 WH BC 纳入土壤会降低 CIF 潜力从 7%到 2.8%。

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研究入侵性杂草水葫芦合成的土壤-生物炭复合材料的开裂和水分可用性。

Investigation of cracking and water availability of soil-biochar composite synthesized from invasive weed water hyacinth.

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