热-水耦合作用下南海深海沉积物抗剪强度变化特征研究。

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-10-10 DOI:10.1038/s41598-025-19493-7

Yan Feng, Qiunan Chen, Lihai Wu, Jinhu Tang, Guangping Liu, Zengliang Wang, Wei Hu, Bingchu Chen, Shunkai Liu

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引用次数: 0

摘要

为研究耦合场作用下南海深海沉积物的力学响应机制，通过三轴剪切试验，系统分析了含水率（15% ~ 35%）、温度（4℃~ 60℃）、围压（100 ~ 300 kPa）对南海深海沉积物不排水抗剪强度的影响。建立了热液耦合模型。结果表明，含水率的增加显著降低了抗剪强度：在低围压下，在含水率为15% ~ 35%的范围内，强度降低了50%，而高围压通过增强颗粒约束，将抗剪强度降低到30%。温度升高加速了水泥软化和颗粒热运动，导致粘聚力从17.6 kPa下降到10.9 kPa，内摩擦角从23.8°下降到16.7°。围压虽能提高水泥强度，但不能逆转高温引起的水泥破坏。改进的热液耦合模型，将水分敏感系数(m)和温度敏感系数(n)结合起来，可以精确预测耦合场效应下的应力-应变关系（相关系数R²> 0.97）。研究结果为南海深海资源开发工程稳定性评价和风险管理提供了定量理论支持。

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Study on variation characteristics of shear strength of deep-sea sediments in the South China sea under thermo-hydraulic coupling.

To investigate the mechanical response mechanisms of deep-sea sediments in the South China Sea under coupled field effects, this study systematically analyzed the influence of moisture content (15%-35%), temperature (4℃-60℃), and confining pressure (100-300 kPa) on their undrained shear strength through triaxial shear tests. A thermohydraulic-coupled model was developed. Results indicate that increased moisture content significantly reduces shear strength: at low confining pressures, strength decreases by 50% across 15%-35% moisture content ranges, while high confining pressures reduce the decrease to 30% by enhancing particle confinement. Temperature elevation accelerates cement softening and particle thermal motion, causing cohesion to drop from 17.6 kPa to 10.9 kPa and internal friction angle from 23.8° to 16.7°. Although confining pressure enhances strength, it cannot reverse cement failure caused by high temperatures. The improved thermohydraulic-coupled model, incorporating moisture content sensitivity coefficient (m) and temperature sensitivity coefficient (n), achieves precise stress-strain relationship predictions under coupled field effects (correlation coefficient R²> 0.97). These findings provide quantitative theoretical support for assessing engineering stability and risk management in resource development of deep-sea areas in the South China Sea.

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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