O. Faloye, E. Ajayi, J. Rostek, T. Babalola, A. Fashina, R. Horn
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引用次数: 1
Abstract
. Studies which evaluated the aggregation effects in biochar-amended soils by determining the saturated hydraulic conductivity and water repellency, in combination with wetting/ drying scenarios are rare. Therefore, the objective of this study is to link water repellency and water retention in biochar-amended soils to the aggregation effect under different pyrolysis conditions and soil textures. Two feedstock sizes; twig and branch-based mango were pyrolysed at 550°, and were then mixed with sandy loam and silt loam at application rates of; 0, 30, 45 and 60 g kg –1 respectively. Sequentially, the soil-biochar mixtures were subjected to five wetting and drying cycles. In each of the cycles, the saturated hydraulic conductivity, and thereafter the contact angles of the soil-biochar mixtures were measured using the sessile drop approach. The results showed that biochar addition decreased the saturated hydraulic conductivity in all cycles. The rigidity effect was more pronounced in soil amended with biochar and produced using twig mango as opposed to the biochar produced using mango branch. A higher rigidity value was measured in the silt loam and sandy loam amended with twig as compared to the branch-based mango which may be attributed to aggregation processes. This also coincides with higher contact angle values and water retention values that were measured using twig as opposed to branch-based mango.
. 通过测定饱和导电性和疏水性来评估生物炭改性土壤中的聚集效应,并结合湿/干情景的研究很少。因此,本研究的目的是将生物炭改性土壤的拒水性和保水性与不同热解条件和土壤质地下的聚集效应联系起来。两种原料尺寸;在550°高温下对嫩枝和枝型芒果进行热解,然后与砂壤土和粉壤土混合,施用量为;分别为0、30、45和60 g kg -1。随后,对土壤-生物炭混合物进行了5个湿润和干燥循环。在每个循环中,使用无根滴法测量土壤-生物炭混合物的饱和水力导率和接触角。结果表明,生物炭的加入降低了各循环的饱和导电性。与使用芒果枝生产的生物炭相比,使用芒果枝进行生物炭改性的土壤的刚性效应更为明显。在粉壤土和砂壤土中测量到的刚性值较高,与枝状芒果相比,这可能归因于聚集过程。这也与用小树枝测量的接触角值和保水值相吻合,而不是用树枝测量的。
期刊介绍:
The journal is focused on the soil-plant-atmosphere system. The journal publishes original research and review papers on any subject regarding soil, plant and atmosphere and the interface in between. Manuscripts on postharvest processing and quality of crops are also welcomed.
Particularly the journal is focused on the following areas:
implications of agricultural land use, soil management and climate change on production of biomass and renewable energy, soil structure, cycling of carbon, water, heat and nutrients, biota, greenhouse gases and environment,
soil-plant-atmosphere continuum and ways of its regulation to increase efficiency of water, energy and chemicals in agriculture,
postharvest management and processing of agricultural and horticultural products in relation to food quality and safety,
mathematical modeling of physical processes affecting environment quality, plant production and postharvest processing,
advances in sensors and communication devices to measure and collect information about physical conditions in agricultural and natural environments.
Papers accepted in the International Agrophysics should reveal substantial novelty and include thoughtful physical, biological and chemical interpretation and accurate description of the methods used.
All manuscripts are initially checked on topic suitability and linguistic quality.