An explicit one‐dimensional consolidation solution with semi‐permeable drainage boundary for unsaturated soil

Summary Existing solutions for analyzing one‐dimensional (1‐D) consolidation of unsaturated soil are only derived to cater to two extreme drainage conditions (fully drained and undrained). This study presents a new explicit solution for 1‐D consolidation of unsaturated soil with semi‐permeable drain...

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Published inInternational journal for numerical and analytical methods in geomechanics Vol. 44; no. 16; pp. 2241 - 2253
Main Authors Zhao, Xudong, Ng, Charles W. W., Zhang, Shuai, Ni, Junjun, Zhou, Chao
Format Journal Article
LanguageEnglish
Published Bognor Regis Wiley Subscription Services, Inc 01.11.2020
Subjects
1‐D consolidation
Computer software
Consolidation
Differential equations
Dimensional analysis
Drainage
eigenfunction expansion method
Eigenfunctions
Eigenvalues
Eigenvectors
Exact solutions
explicit analytical solution
External pressure
Independent variables
Ordinary differential equations
semi‐permeable boundary
Soil
Soil analysis
Soil permeability
Soils
unsaturated soil
Unsaturated soils
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Summary:Summary Existing solutions for analyzing one‐dimensional (1‐D) consolidation of unsaturated soil are only derived to cater to two extreme drainage conditions (fully drained and undrained). This study presents a new explicit solution for 1‐D consolidation of unsaturated soil with semi‐permeable drainage boundary. Based on the assumptions of two independent stress variables and the governing equations proposed by Fredlund, the eigenfunction expansion method is adopted to develop an explicit analytical solution to calculate excess pore‐water and pore‐air pressures in an unsaturated soil when it is subjected to external loads. The developed general solutions are expressed in terms of depth, z, and time, t. For the semi‐permeable drainage boundary, eigenvalues and eigenfunctions in the space domain are developed. The technique of Laplace transform is used to solve the coupled ordinary differential equations in the time domain. The newly derived explicit solution is verified with the existing semi‐analytical method in the literature, and an excellent agreement is obtained. Compared with the semi‐analytical solution, the newly derived analytical solution is more straightforward and explicit so that this solution is relatively easier to be implemented into a computer program to carry out a preliminary assessment of 1‐D consolidation of unsaturated soil.
ISSN:0363-9061
1096-9853
DOI:10.1002/nag.3126