Study on time effect and prediction model of shear strength of root-soil complex under dry-wet cycle

Zhengjun Mao , Xu Ma , Yuncen Liu , Mimi Geng , Yanshan Tian , Jiewen Sun , Zhijie Yang
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Abstract

Triaxial compression tests were conducted on the alfalfa root-loess complex at different growthperiods obtained through artificial planting. The research focused on analyzing the time variation law of the shear strength index and deformation index of the alfalfa root-loess complex under dry-wet cycles. Additionally, the time effect of the shear strength index of the alfalfa root-loess complex under dry-wet cycles was analyzed and its prediction model was proposed. The results show that the PG-DWC (dry-wet cycle caused by plant water management during plant growth period) causes the peak strength of plain soil to change in a "V" shape with the increase of growth period, and the peak strength of alfalfa root-loess complex is higher than that of plain soil at the same growth period. The deterioration of the peak strength of alfalfa root-loess complex in the same growth period is aggravated with the increase of drying and wetting cycles. Compared with the 0 days growth period, the effective cohesion of alfalfa root-loess complex under different dry-wet cycles maximum increase rate is at the 180 days, which are 33.88%, 46.05%, 30.12% and 216.02%, respectively. When the number of dry-wet cycles is constant, the effective cohesion of the alfalfa root-loess complex overall increases with the growth period. However, it gradually decreases comparedwith the previous growth period, and the minimum increase rate are all at the 180 days. For the same growth period, the effective cohesion of the alfalfa root-loess complex decreases with the increase of the number of dry-wet cycles. This indicates that EC-DWC (the dry-wet cycles caused by extreme natural conditions such as continuous rain) have a detrimental effect on the time effect of the shear strength of the alfalfa root-loess complex. Finally, based on the formula of total deterioration, a prediction model for the shear strength of the alfalfa root-loess complex under dry-wet cycles was proposed, which exhibits high prediction accuracy. The research results provide useful guidance for the understanding of mechanical behavior and structural damage evolution of root-soil composite.

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干湿循环下根土复合体剪切强度的时间效应和预测模型研究
对通过人工种植获得的不同生长期的紫花苜蓿无根复合体进行了三轴压缩试验。研究重点分析了干湿循环条件下紫花苜蓿无根复合体剪切强度指数和变形指数的时间变化规律。此外,还分析了干湿循环下苜蓿无根复合体剪切强度指数的时间效应,并提出了其预测模型。结果表明,PG-DWC(植物生长期植物水分管理引起的干湿循环)会使普通土壤的峰值强度随生长期的延长呈 "V "形变化,而苜蓿无根复合体的峰值强度高于相同生长期的普通土壤。随着干燥和湿润周期的增加,同一生长期内苜蓿无根复合土峰值强度的恶化加剧。与 0 天生长期相比,苜蓿无根复合体在不同干湿循环下的有效内聚力最大增长率出现在 180 天,分别为 33.88%、46.05%、30.12% 和 216.02%。当干湿循环次数不变时,苜蓿无根复合体的有效内聚力总体上随着生长期的延长而增加。但与前一个生长期相比,有效内聚力逐渐减小,最小增幅均出现在 180 天时。在同一生长期,苜蓿无根复合体的有效内聚力随干湿循环次数的增加而降低。这表明,EC-DWC(由连续降雨等极端自然条件引起的干湿循环)对苜蓿无根复合体剪切强度的时间效应有不利影响。最后,根据总劣化公式,提出了干湿循环条件下苜蓿无根复合体抗剪强度的预测模型,该模型具有较高的预测精度。研究成果为理解根-土复合体的力学行为和结构损伤演变提供了有益的指导。
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