Understanding the rheological properties of clayey soils is significant for construction and geotechnical engineering, as these properties influence the stability and performance of building materials and structures. This study offers a new prospective for the rheological behavior of soils with water content near the liquid limit. Steady-state and dynamic rheological tests were conducted on kaolin, montmorillonite, and other three mixed clays of them at different water contents. In addition, microstructural analysis was performed to explain the microscopic mechanisms influencing the rheological responses of clays. The results show that for all the clays, the yield stress decreases with increasing water content. With the increase of shear rate, the viscosity first decreases rapidly and then decreases slowly. Clay mixtures exhibit greater microstructural stability than pure kaolin and montmorillonite, resulting in higher yield stress. Furthermore, dynamic shear testing provided insights into energy storage and loss modulus of clays near the solid-liquid transition phase. The proposed dynamic yield stress model effectively describes yield stress variation with the liquid limit under dynamic loading, relevant for assessing soil liquefaction potential and seismic resilience of structures. These findings offer valuable guidance for optimizing soil behavior in construction and enhancing structural performance in clay-rich regions.

Submarine debris flows are events that occur with great frequency on a geological scale and can cause major damage to offshore structures or even loss of human life. Understanding the mechanisms involved in the development of a debris flow requires not only knowledge of soil mechanics, but also knowledge of fluid mechanics, since the incorporation of water during the flow causes changes in shear strength. Unlike soils, the shear strength of fluids is represented by mathematical models called rheological models. The objective of this paper is to propose a new rheological model capable of representing the changes caused by water entrainment into a submarine debris flow, by correlating it with the Liquidity Index of the soil. A rheological analysis of marine clay samples from the pre-salt layer has made it possible to represent the variation in strength due to water content. The influence of water content and velocity on flow behavior has also been studied through the analysis of centrifuge tests performed in a previous study.

The construction process of earth pressure balance shield (EPBS) generates a large amount of shield slag. In China, the conventional methods for treating shield slag involve crude landfill and stockpiling, resulting in increased cost and significant environmental issues. To expand the recycling of shield slag, this study proposes to use waste silty clay to completely replace bentonite as a conditioner in coarse-grained strata. Firstly, the physical properties of silty clay slurries are investigated with four additives. There are six modified silty clay slurries with good improved performance. Then, analyzing the rheological properties of six modified silty clay slurries, and verifying the feasibility of replacing bentonite slurry with modified silty clay slurry. Next, scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR) and Zeta potential were used to analyse the micromechanisms, molecular structures and molecular forces of 14 % bentonite slurry, silty clay slurry with a soil-water ratio of 1:1, sodium carbonate 3 % and sodium silicate 0.1 % in a silty clay slurry with a soil-water ratio of 1:1. Finally, the slump test was carried out to verify the improvement effect of the modified silty clay slurry on the shield slag. The results show that sodium carbonate modified silty clay slurry has a higher interlayer water content and greater ion exchange capacity. When the soil-water ratio is 1:1 and the concentration of sodium carbonate is 3 %, the apparent viscosity and shear force of the modified silty clay slurries are between those of bentonite slurries with a concentration of 10 % and 14%. Additionally, the modified silty clay slurry showed a stable microstructure and good residue amendment effect, making it suitable as a soil conditioner during EPBS construction in coarse-grained strata. This study offers a viable approach for recycling EPBS slurry.