生物炭改变两种农业土壤的导电性并影响养分淋失

4区 农林科学 Q2 Agricultural and Biological Sciences
D. Gelardi, Irfan Ainuddin, D. Rippner, J. Patiño, M. A. Abou Najm, S. Parikh
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引用次数: 3

摘要

摘要据称,生物炭通过改变饱和水力电导率(Ksat)和通过化学或物理手段增加养分保留,添加到土壤中可以提供农业效益。尽管人们对生物炭的兴趣和研究有所增加,但由于生物炭原料、生产方法、生产温度和土壤质地的差异,生物炭能否提供这些农艺效益仍存在不确定性。在本项目中,使用不同原料和生产温度的生物炭进行了一系列实验,以确定可能优化农业效益的生物炭参数。用7种不同的生物炭进行了吸附实验,以确定铵和硝的吸附效率。只有一种生物炭有效地保留了硝酸盐,而所有生物炭都结合了铵。选择3种结合能力最强的生物炭(由500和800°C的杏仁壳(AS500和AS800)和500°C的软木(SW500)制成)进行柱状实验。将生物炭分别以0%和2% (w/w)添加到砂质壤土和粉质壤土中,并测量了ksat2。生物炭使两种土壤的Ksat降低了64% - 80%,但AS800除外,它使粉砂土的Ksat增加了98%。测定了砂壤土柱中硝态氮和铵态氮的突破曲线,以及渗滤液的浓度。全生物炭显著降低了渗滤液中铵的含量,减少了22%至78%,并减缓了其在土壤剖面中的移动。氨潴留与高阳离子交换能力和高氧碳比有关,表明生物炭改性土壤中铵潴留的主要控制因素是生物炭表面与铵的化学亲和力。生物炭对硝酸盐释放的时间几乎没有影响,只有SW500能使总释放量减少27%至36%。生物炭保留硝酸盐的能力可能与高微孔比表面积有关,这表明是物理捕获而不是化学结合。总之,这项工作揭示了生物炭可能改变土壤的化学和物理结合手段,从而影响农业生产的养分淋失和水力传导性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biochar alters hydraulic conductivity and impacts nutrient leaching in two agricultural soils
Abstract. Biochar is purported to provide agricultural benefits when added to the soil, through changes in saturated hydraulic conductivity (Ksat) and increased nutrient retention through chemical or physical means. Despite increased interest and investigation, there remains uncertainty regarding the ability of biochar to deliver these agronomic benefits due to differences in biochar feedstock, production method, production temperature, and soil texture. In this project, a suite of experiments was carried out using biochars of diverse feedstocks and production temperatures, in order to determine the biochar parameters which may optimize agricultural benefits. Sorption experiments were performed with seven distinct biochars to determine sorption efficiencies for ammonium and nitrate. Only one biochar effectively retained nitrate, while all biochars bound ammonium. The three biochars with the highest binding capacities (produced from almond shell at 500 and 800 ∘C (AS500 and AS800) and softwood at 500 ∘C (SW500)) were chosen for column experiments. Biochars were amended to a sandy loam and a silt loam at 0 % and 2 % (w/w), and Ksat was measured. Biochars reduced Ksat in both soils by 64 %–80 %, with the exception of AS800, which increased Ksat by 98 % in the silt loam. Breakthrough curves for nitrate and ammonium, as well as leachate nutrient concentration, were also measured in the sandy loam columns. All biochars significantly decreased the quantity of ammonium in the leachate, by 22 % to 78 %, and slowed its movement through the soil profile. Ammonium retention was linked to high cation exchange capacity and a high oxygen-to-carbon ratio, indicating that the primary control of ammonium retention in biochar-amended soils is the chemical affinity between biochar surfaces and ammonium. Biochars had little to no effect on the timing of nitrate release, and only SW500 decreased total quantity, by 27 % to 36 %. The ability of biochar to retain nitrate may be linked to high micropore specific surface area, suggesting a physical entrapment rather than a chemical binding. Together, this work sheds new light on the combined chemical and physical means by which biochar may alter soils to impact nutrient leaching and hydraulic conductivity for agricultural production.
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来源期刊
Soil Science
Soil Science 农林科学-土壤科学
CiteScore
2.70
自引率
0.00%
发文量
0
审稿时长
4.4 months
期刊介绍: Cessation.Soil Science satisfies the professional needs of all scientists and laboratory personnel involved in soil and plant research by publishing primary research reports and critical reviews of basic and applied soil science, especially as it relates to soil and plant studies and general environmental soil science. Each month, Soil Science presents authoritative research articles from an impressive array of discipline: soil chemistry and biochemistry, physics, fertility and nutrition, soil genesis and morphology, soil microbiology and mineralogy. Of immediate relevance to soil scientists-both industrial and academic-this unique publication also has long-range value for agronomists and environmental scientists.
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