Tianchi Wu scite author profile

Tianchi Wu

4Publications

5Citation Statements Received

103Citation Statements Given

How they've been cited

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106

103

Affiliations

Cardiff University, Beijing Jiaotong University

Publications

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Microstructurally Related Model for Predicting Behavior of Unsaturated Soils with Double Porosity in Triaxial Space

Cai

Cleall

et al. 2022

Int. J. Geomech.

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Microstructure can have an important impact on the hydraulic and mechanical behaviour of unsaturated soil and so it is necessary for it to be considered in constitutive models to enable accurate predictions of soil behaviour. This paper focuses on constitutive modelling of soils exhibiting a dual-porosity structure. Based on the assumption that macro and micropores contained in the double porosity structure have different influences on the mechanical and hydraulic behaviour, the effective degree of saturation was selected as a microstructural index. This microstructural index was implemented within a Bishop's effective stress based approach and the Glasgow Coupled Model and the Modified Camclay Model were adopted as the basic framework for the development of a constitutive model. Typical samples of low-expansive, nonexpansive and collapsible soils with dual porosity were selected to validate the model's performance, with the model found to perform well when compared with experimental data in terms of isotropic compression, triaxial shear and wetting tests.

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Numerical Implementation of a Hydro-Mechanical Coupling Constitutive Model for Unsaturated Soil Considering the Effect of Micro-Pore Structure

Cai

Han

et al. 2021

Applied Sciences

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An unsaturated soil constitutive model considering the influence of microscopic pore structure can more accurately describe the hydraulic–mechanical behavior of unsaturated soil, but its numerical implementation is more complicated. Based on the fully implicit Euler backward integration algorithm, the ABAQUS software is used to develop the established hydro-mechanical coupling constitutive model for unsaturated soil, considering the influence of micro-pore structure, and a new User-defined Material Mechanical Behavior (UMAT) subroutine is established to realize the numerical application of the proposed model. The developed numerical program is used to simulate the drying/wetting cycle process of the standard triaxial specimen. The simulation results are basically consistent with those calculated by the Fortran program, which verifies the rationality of the developed numerical program.

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Consideration of microstructure in modelling the hydro-mechanical behaviour of unsaturated soils

Cleall

Tripathy

et al. 2023

E3S Web of Conf.

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The hydro-mechanical behaviour of unsaturated soils is often highly influenced by the microstructure; therefore, it can be beneficial to consider the effect of microstructure in a hydro-mechanical constitutive model. This paper considers the use of a microstructure-related model that adopts the effective degree of saturation as a microstructural index. The model can be used to reproduce the hydro-mechanical behaviour while the effect of the microstructure is considered. For comparison, a non-microstructuredependent model is also employed. The models are applied to simulate the behaviour of two different soilsand a comparison of the models’ performance in simulating triaxial test behaviour is made. Based on the comparison with experimental results and the non-microstructure-dependent model, it can be concluded thatthe adoption of the effective degree of saturation is beneficial to studying the hydro-mechanical behaviour of unsaturated soils affected by the microstructure.

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A deformation-dependent soil-water characteristic surface model considering hysteresis

Cai

Li³

et al. 2020

E3S Web Conf.

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The soil-water characteristic surface model plays an essential part in predicting the hydraulic behaviour of unsaturated soils. Based on the theory of plasticity bounding surface, this paper presents a three-dimensional soil-water characteristic surface model considering the effects of deformation and hysteresis. Suction and void ratio are adopted as independent variables, while the degree of saturation is adopted as a dependent variable. A new mapping rule is used where the distance between the current position and its image point can be calculated as a difference in the degree of saturation axis. The model is verified by comparing with drying-wetting tests on bentonite/kaolin mix and pearl clay. The efficiency of the proposed model is proven by validation tests.

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Tianchi Wu

Microstructurally Related Model for Predicting Behavior of Unsaturated Soils with Double Porosity in Triaxial Space

Numerical Implementation of a Hydro-Mechanical Coupling Constitutive Model for Unsaturated Soil Considering the Effect of Micro-Pore Structure

Consideration of microstructure in modelling the hydro-mechanical behaviour of unsaturated soils

A deformation-dependent soil-water characteristic surface model considering hysteresis

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