Unconventional effective stress: concept and applications

Chuanzhong Jiang

doi:10.26182/77pt-f982

Unconventional effective stress: concept and applications

Chuanzhong Jiang

School of Engineering

Research output: Thesis › Doctoral Thesis

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Abstract

Coal seams are promising for energy storage and CO2 sequestration. Experiments show that coal properties, including permeability and Young’s modulus, evolve during gas adsorption in ways that the conventional effective stress (CES) theory cannot predict. This thesis resolves the gap by proposing unconventional effective stress (UES), which unifies sorption-induced processes through a “fictitious stress” quantifying self-constrained or facilitated swelling. Constitutive models built on UES reproduce observations. Embedded in a coupled multi-component hydro-mechanical dual-porosity framework, these models assess symbiotic hydrogen–CO2 storage, demonstrating that UES captures property evolution and informs practical strategies for large-scale hydrogen storage with simultaneous CO2 sequestration.

Original language	English
Qualification	Doctor of Philosophy
Awarding Institution	The University of Western Australia
Supervisors/Advisors	Liu, Jishan, Supervisor Leong, Yee-Kwong, Supervisor Elsworth, Derek, Supervisor, External person
Award date	28 Jan 2026
DOIs	https://doi.org/10.26182/77pt-f982
Publication status	Unpublished - 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

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10.26182/77pt-f982

THESIS - DOCTOR OF PHILOSOPHY - JIANG Chuanzhong - 2025
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Exploratory assessment of symbiotic hydrogen storage and CO₂ sequestration in coal seams
Jiang, C., Liu, J. & Elsworth, D., 1 Jan 2026, In: Energy. 342, 139773.
Research output: Contribution to journal › Article › peer-review

Open Access
Evolution of coal permeability during gas/energy storage
Jiang, C., Liu, J., Leong, Y. K. & Elsworth, D., 31 Jan 2024, In: International Journal of Hydrogen Energy. 53, p. 1373-1386 14 p.
Research output: Contribution to journal › Article › peer-review

Open Access
16 Link opens in a new tab Citations (Scopus)
Feasibility Assessment of Symbiotic Processes Between Hydrogen and CO2 Storage in Coal Seams of Various Ranks
Jiang, C., Liu, J. & Elsworth, D., 11 Oct 2024, APOGCE 2024 - SPE Asia Pacific Oil and Gas Conference and Exhibition. Society of Petroleum Engineers, 26 p. SPE-221263-MS
Research output: Chapter in Book/Conference paper › Conference paper › peer-review
2 Link opens in a new tab Citations (Scopus)

Cite this

@phdthesis{f5c9c869c9d641cd8225f2763e67db9c,

title = "Unconventional effective stress: concept and applications",

abstract = "Coal seams are promising for energy storage and CO2 sequestration. Experiments show that coal properties, including permeability and Young{\textquoteright}s modulus, evolve during gas adsorption in ways that the conventional effective stress (CES) theory cannot predict. This thesis resolves the gap by proposing unconventional effective stress (UES), which unifies sorption-induced processes through a “fictitious stress” quantifying self-constrained or facilitated swelling. Constitutive models built on UES reproduce observations. Embedded in a coupled multi-component hydro-mechanical dual-porosity framework, these models assess symbiotic hydrogen–CO2 storage, demonstrating that UES captures property evolution and informs practical strategies for large-scale hydrogen storage with simultaneous CO2 sequestration.",

keywords = "Coal, Gas adsorption, Fictitious stress, EFFECTIVE STRESS, PERMEABILITY EVOLUTION, Young's modulus evolution, Hydrogen storage, Carbon Dioxide Sequestration",

author = "Chuanzhong Jiang",

year = "2025",

doi = "10.26182/77pt-f982",

language = "English",

school = "The University of Western Australia",

}

TY - BOOK

T1 - Unconventional effective stress: concept and applications

AU - Jiang, Chuanzhong

PY - 2025

Y1 - 2025

N2 - Coal seams are promising for energy storage and CO2 sequestration. Experiments show that coal properties, including permeability and Young’s modulus, evolve during gas adsorption in ways that the conventional effective stress (CES) theory cannot predict. This thesis resolves the gap by proposing unconventional effective stress (UES), which unifies sorption-induced processes through a “fictitious stress” quantifying self-constrained or facilitated swelling. Constitutive models built on UES reproduce observations. Embedded in a coupled multi-component hydro-mechanical dual-porosity framework, these models assess symbiotic hydrogen–CO2 storage, demonstrating that UES captures property evolution and informs practical strategies for large-scale hydrogen storage with simultaneous CO2 sequestration.

AB - Coal seams are promising for energy storage and CO2 sequestration. Experiments show that coal properties, including permeability and Young’s modulus, evolve during gas adsorption in ways that the conventional effective stress (CES) theory cannot predict. This thesis resolves the gap by proposing unconventional effective stress (UES), which unifies sorption-induced processes through a “fictitious stress” quantifying self-constrained or facilitated swelling. Constitutive models built on UES reproduce observations. Embedded in a coupled multi-component hydro-mechanical dual-porosity framework, these models assess symbiotic hydrogen–CO2 storage, demonstrating that UES captures property evolution and informs practical strategies for large-scale hydrogen storage with simultaneous CO2 sequestration.

KW - Coal

KW - Gas adsorption

KW - Fictitious stress

KW - EFFECTIVE STRESS

KW - PERMEABILITY EVOLUTION

KW - Young's modulus evolution

KW - Hydrogen storage

KW - Carbon Dioxide Sequestration

U2 - 10.26182/77pt-f982

DO - 10.26182/77pt-f982

M3 - Doctoral Thesis

ER -

Unconventional effective stress: concept and applications

Abstract

UN SDGs

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Research output

Exploratory assessment of symbiotic hydrogen storage and CO2 sequestration in coal seams

Evolution of coal permeability during gas/energy storage

Feasibility Assessment of Symbiotic Processes Between Hydrogen and CO2 Storage in Coal Seams of Various Ranks

Cite this

Exploratory assessment of symbiotic hydrogen storage and CO₂ sequestration in coal seams