Evaluation of total infiltration and storage capacities for different soil types in Sarawak using SWMM

King Kuok Kuok, Po Chan Chiu, Md. Rezaur Rahman, Khairul Anwar bin Mohamad Said, Mei Yun Chin
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Abstract

Abstract Climate change and irresponsible urbanization practices are anticipated to further exacerbate flood risk. The different soil types’ physical, chemical, and biological characteristics significantly impact surface water movement, porosity, permeability, and infiltration potential. Therefore, soil infiltration is perhaps the most challenging and crucial process to characterize on a field scale. Various methods have been developed to measure the infiltration rate empirically and theoretically. However, the relationship between different soil types and infiltration rates in Sarawak remains unknown as no previous study has been conducted. This study uses the Storm Water Management Model (SWMM) to evaluate the infiltration rates for five different soil types: clay, clay loam, loam, sandy loam, and sand. 30 samples of various types and soil depths were examined at intervals of 0.5 m, 1.0 m, 1.5 m, 2.0 m, 2.5 m, and 3 m. The study was carried out using a standardized slope of 0.7% and an impervious land of 25% with a catchment size of 2 acres. Extreme rainfall data on the 5th and 6th of December 2021 was input into the infiltration model. Results showed that the difference between initial and final water storage of all the investigated soil depths for clay, clay loam, loam, sandy loam, and sand was found to be 48.42 mm, 51.20 mm, 58.01 mm, 66.96 mm, and 115.54 mm, respectively. The findings demonstrated that clay has the lowest water storage capability, followed by clay loam, loam, and sandy loam. Sand could store a comparatively large amount of rainwater. In contrast, sand has the highest infiltration rate with 2.541 mm/h, followed by sandy loam with 1.835 mm/h, loam with 1.432 mm/h, clay loam with 1.039 mm/h. Clay has the lowest infiltration rate, with 0.852 mm/h. This research concluded that sandy soil could significantly reduce surface runoff and help reduce flood risk in urban regions.
利用SWMM评价砂拉越不同土壤类型的总入渗和储水量
气候变化和不负责任的城市化实践预计将进一步加剧洪水风险。不同土壤类型的物理、化学和生物特性显著影响地表水的运动、孔隙度、渗透率和入渗势。因此,土壤入渗可能是最具挑战性和最关键的过程,在田间尺度上进行表征。各种测量入渗速率的方法已经发展到经验和理论。然而,沙捞越不同土壤类型与入渗率之间的关系仍然未知,因为之前没有进行过研究。本研究使用雨水管理模型(SWMM)来评估五种不同土壤类型的入渗速率:粘土、粘壤土、壤土、砂壤土和沙土。在0.5 m, 1.0 m, 1.5 m, 2.0 m, 2.5 m和3 m的间隔内检查了30个不同类型和土壤深度的样品。该研究采用0.7%的标准坡度和25%的不透水土地,集水区面积为2英亩。入渗模型输入2021年12月5日和6日的极端降水数据。结果表明:粘土、粘壤土、壤土、砂壤土和砂土的初始和最终储水量差异分别为48.42 mm、51.20 mm、58.01 mm、66.96 mm和115.54 mm;结果表明,粘土的储水能力最低,其次是粘土壤土、壤土和砂壤土。沙子可以储存相对大量的雨水。砂土入渗速率最高,为2.541 mm/h,其次是砂质壤土(1.835 mm/h)、壤土(1.432 mm/h)和粘土壤土(1.039 mm/h)。粘土的入渗速率最低,为0.852 mm/h。研究表明,沙质土壤可以显著减少地表径流,有助于降低城市地区的洪水风险。
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来源期刊
Discover Water
Discover Water water research-
自引率
0.00%
发文量
13
审稿时长
23 days
期刊介绍: Discover Water is part of the Discover journal series committed to providing a streamlined submission process, rapid review and publication, and a high level of author service at every stage. It is an open access, community-focussed journal publishing research from across all fields relevant to water research. Discover Water is a broad, open access journal publishing research from across all fields relevant to the science and technology of water research and management. Discover Water covers not only research on water as a resource, for example for drinking, agriculture and sanitation, but also the impact of society on water, such as the effect of human activities on water availability and pollution. As such it looks at the overall role of water at a global level, including physical, chemical, biological, and ecological processes, and social, policy, and public health implications. It is also intended that articles published in Discover Water may help to support and accelerate United Nations Sustainable Development Goal 6: ‘Clean water and sanitation’.
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