Grain-size dependence of water retention in a model aggregated soil

[Display omitted] •The amount of water retention in a model soil composed of aggregated glass beads was experimentally examined.•Relation between the retained water amount and size parameters of aggregates was discussed.•Specific size value to maximize the water retention was obtained. We experiment...

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Bibliographic Details
Published in:Advanced powder technology : the international journal of the Society of Powder Technology, Japan Japan, 2023-01, Vol.34 (1), p.103896, Article 103896
Main Authors: Yasuda, Hyuga, Katsura, Makoto, Katsuragi, Hiroaki
Format: Article
Language:English
Subjects:
Aggregated structure
macroscopic pore
microscopic pore
water content
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Summary:[Display omitted] •The amount of water retention in a model soil composed of aggregated glass beads was experimentally examined.•Relation between the retained water amount and size parameters of aggregates was discussed.•Specific size value to maximize the water retention was obtained. We experimentally examined the amount of water retention in a model soil composed of aggregated glass beads. The model soil was characterized by two size parameters: size of aggregates D and size of monomer particles (composing aggregates) d. In the experiment, water was sprinkled on the model-soil system that has an open top surface and drainable sieve bottom. When the sprinkled water amount exceeded a threshold (retainable limit), draining flux balanced with the sprinkled flux. The weight variations of retained and drained water were measured to confirm this balanced (steady) state and quantify the retained water. We defined the weight of the retained water in this steady state as W0 and examined the relationship among W0,d and D. As a result, it was revealed that W0 increases as d decreases simply due to the capillary effects. Regarding D dependence, it turned out that W0 becomes the maximum around D≃500μm. The value of D maximizing water retention is determined by the void formation due to the aggregated structure, capillary effect, and gravity.
ISSN:0921-8831
1568-5527
DOI:10.1016/j.apt.2022.103896