Please use this identifier to cite or link to this item: http://hdl.handle.net/10397/119683
DC FieldValueLanguage
dc.contributorDepartment of Civil and Environmental Engineering-
dc.contributorResearch Institute for Land and Space-
dc.creatorLi, PL-
dc.creatorYin, ZY-
dc.creatorSong, ZY-
dc.creatorSong, DB-
dc.creatorYin, JH-
dc.date.accessioned2026-07-06T02:29:16Z-
dc.date.available2026-07-06T02:29:16Z-
dc.identifier.issn0008-3674-
dc.identifier.urihttp://hdl.handle.net/10397/119683-
dc.language.isoenen_US
dc.publisherCanadian Science Publishingen_US
dc.rights© 2026 The Authors. Permission for reuse (free in most cases) can be obtained from copyright.com (https://marketplace.copyright.com/rs-ui-web/mp).en_US
dc.rightsThis is the accepted version of the work. The final published article is available at https://doi.org/10.1139/cgj-2025-0793.en_US
dc.subjectClayen_US
dc.subjectGeneralized effective stressen_US
dc.subjectHMC couplingen_US
dc.subjectPore-chemistry effecten_US
dc.subjectTime dependenceen_US
dc.titleA fully coupled hydro-mechanical-chemo model for saturated clayey soils with pore-chemistry-induced and time-dependent deformationen_US
dc.typeJournal/Magazine Articleen_US
dc.identifier.spage1-
dc.identifier.epage23-
dc.identifier.volume63-
dc.identifier.doi10.1139/cgj-2025-0793-
dcterms.abstractHydro-mechanical-chemo (HMC) coupling in clayey soils governs the long-term performance of critical infrastructures exposed to chemical environments. Existing models predominantly emphasize the one-way effect of consolidation on solute transport, with the influence of pore-water chemistry on soil deformation remaining insufficiently addressed. This study develops a fully coupled HMC elastic–viscoplastic (EVP) numerical model. It integrates consolidation and solute transport processes by introducing a novel chemical-influenced, time-dependent constitutive relationship. This relationship is formulated as a chemically enhanced EVP (C-EVP) framework by introducing a generalized effective stress concept instead of classical Terzaghi effective stress. The governing equations, rigorously derived from the C-EVP framework, form the core of the proposed HMC model and are solved using an implicit finite-difference scheme. The present solution is further validated against analytical solutions of a simplified HMC model for elastic soil and oedometer tests under combined mechanical and chemical loadings. The model successfully reproduces chemically induced compression, volume rebound under salinity reduction, and salinity-dependent creep under constant load. These results demonstrate that the proposed HMC formulation, which explicitly incorporates the C-EVP framework, provides a rigorous and reliable tool for predicting long-term settlement and solute evolution in clayey soils exposed to chemical environment.-
dcterms.accessRightsopen accessen_US
dcterms.bibliographicCitationCanadian geotechnical journal, 2026, v. 63, p. 1-23-
dcterms.isPartOfCanadian geotechnical journal-
dcterms.issued2026-
dc.identifier.scopus2-s2.0-105037177044-
dc.identifier.eissn1208-6010-
dc.description.validate202607 bcjz-
dc.description.oaAccepted Manuscripten_US
dc.identifier.SubFormIDG001946/2026-06en_US
dc.description.fundingSourceRGCen_US
dc.description.fundingSourceOthersen_US
dc.description.fundingTextThe work in this paper is supported by three projects (N_PolyU534/20, E-PolyU501/24, 15226322) from Research Grants Council (RGC) of Hong Kong Special Administrative Region Government of China, and by the State Key Laboratory of Climate Resilience for Coastal Cities at the Hong Kong Polytechnic University. The authors also acknowledge the financial supports from Research Institute for Sustainable Urban Development of The Hong Kong Polytechnic University.en_US
dc.description.pubStatusPublisheden_US
dc.description.oaCategoryGreen (AAM)en_US
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