Physics-based characterization of complex geomaterials using stress waves based on a hybrid poromechanical and inverse method

dc.contributor.authorLiu, Hongwei
dc.contributor.examiningcommitteeHollaender, Hartmut (Civil Engineering) Ashraf, Ahmed (Electrical and Computer Engineering) Chalaturnyk, Rick (Civil and Environmental Engineering, University of Alberta)en_US
dc.contributor.supervisorMaghoul, Pooneh (Civil Engineering) Shalaby, Ahmed (Civil Engineering)en_US
dc.date.accessioned2021-11-04T17:08:54Z
dc.date.available2021-11-04T17:08:54Z
dc.date.copyright2021-11-02
dc.date.issued2021en_US
dc.date.submitted2021-11-02T15:59:14Zen_US
dc.degree.disciplineCivil Engineeringen_US
dc.degree.levelDoctor of Philosophy (Ph.D.)en_US
dc.description.abstractNon-destructive testing (NDT) plays an important role in the engineering, construction, and geophysical fields. The application of NDT in civil engineering is broad from quality control, structural health monitoring of infrastructure, geophysical and geotechnical field investigation and material characterization to detection of underground anomaly, among others. One of the frequently used NDT techniques for the characterization of geomaterials is based on the propagation of stress waves generated by an excitation source. However, the existing signal interpretation methods still predominantly rely on empirical relations or subjective judgements that are insufficient for the characterization of multiphase complex geomaterials. This research aims to develop novel physics-based signal interpretation methods to characterize physical and mechanical properties of multiphase geomaterials in both field and laboratory investigation scales. Several hybrid inverse and poromechanical models are developed to characterize dry, saturated, and frozen geomaterials subject to stress waves. First, a highly-efficient semi-analytical elastodynamic forward solver was proposed for the Multichannel Analysis of Surface Waves using the spectral element technique to determine effectively and efficiently the soil stratigraphy as well as soil properties. Next, a coupled piezoelectric and solid mechanics model is proposed to study the real response of the bender element (BE) and its interaction with soil samples in the BE test. A comprehensive laboratory investigation is also performed to better understand the response of the BEs inside different soil types. Then, a two-phase poromechanics-based signal interpretation model is developed for laboratory-scale ultrasonic testing to determine the physical and mechanical properties of saturated soil samples based on the distribution of stress waves. Subsequently, a three-phase poromechanical transfer function model is developed using the spectral element technique for pore-scale characterizations of permafrost samples. Furthermore, a comprehensive ultrasonic testing program is conducted to determine the properties of permafrost samples (e.g., ice content, unfrozen water content, porosity, soil type, and mechanical properties) reconstituted in the laboratory. Thereafter, a hybrid inverse and three-phase poromechanical approach is proposed for in-situ characterization of permafrost sites using surface wave techniques. Finally, the GeoNDT software developed to provide physics-based solutions for the interpretation of NDT measurements used in geotechnical and geophysical applications is presented.en_US
dc.description.noteFebruary 2022en_US
dc.identifier.citationLiu, H., Maghoul, P., Shalaby, A., Bahari, A., & Moradi, F. (2020). Integrated approach for the MASW dispersion analysis using the spectral element technique and trust region reflective method. Computers and Geotechnics, 125, 103689.en_US
dc.identifier.citationLiu, H., Cascante, G., Maghoul, P., & Shalaby, A. (2021). Experimental Investigation and Numerical Modeling of Piezoelectric Bender Element Motion and Wave Propagation Analysis in Soils. Canadian Geotechnical Journal, (ja).en_US
dc.identifier.citationLiu, H., Maghoul, P., & Shalaby, A. (2020). Laboratory-scale characterization of saturated soil samples through ultrasonic techniques. Scientific reports, 10(1), 1-17.en_US
dc.identifier.urihttp://hdl.handle.net/1993/36098
dc.language.isoengen_US
dc.rightsopen accessen_US
dc.subjectNon-destructive testingen_US
dc.subjectPermafrosten_US
dc.subjectUltrasonicen_US
dc.subjectPoroelasticityen_US
dc.subjectBender elementen_US
dc.subjectMASWen_US
dc.subjectTransfer functionen_US
dc.subjectSpectral element methoden_US
dc.subjectRayleigh wavesen_US
dc.subjectDispersionen_US
dc.subjectIce contenten_US
dc.subjectPiezoelectricen_US
dc.subjectGeophysicsen_US
dc.titlePhysics-based characterization of complex geomaterials using stress waves based on a hybrid poromechanical and inverse methoden_US
dc.typedoctoral thesisen_US
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