1. Novel sensing technologies for civil infrastructure

The Smart Geotechnology laboratory exploresvarious aspects of soil-structure interaction problems through novel sensing techniques and investigation of strain distribution and stress mobilizations in composite structures and foundation systems. The research focuses on the use of
high-performance materials, such as high-strength steel materials, in foundation engineering and underground construction. Advanced instrumentation techniques including those with fibre optics sensing are investigated and deployed in field and laboratory studies.

Selected Projects
Straindevelopments in composite structural elements & high-strength steel in foundations

Composite structural elements, such asconcrete-filled steel tube utilizes the confinements provided by steel tube to enhance the performance of concrete column, and can have wide range of applications in superstructures and substructures. The strain developments and interaction between these elements are, however, not well understood. The high-resolution optical fibre optic sensors enable the strain developments can
be accurately captured, providing a new means to understand the interaction between concrete and steel tubular structures of different geometries.

The use of high-strength steel asfoundation elements, such as socketed H-piles, is associated with clear benefits. With the abovementioned sensing technology, the strain developments in the steel H section, grout and surrounding geomaterials can be revealed. The available bond strengths between different components can be determined and the new data shed new insights to the behaviour of these foundation components, inorder to promote their application in construction.

2. Reliability of geotechnical systems

Reliability analyses aims to quantify the propagation of geotechnical uncertainty, such as uncertainty in loads and material resistances, into the uncertainty in system performance. The measure of reliability, i.e. reliability index β, is more meaningful and explicit than the factor of safety FS, because it describes safety by the number of standard deviations, separating the best estimate of FS from its defined failure value of 1.0. A popular approach to evaluate reliability index is the First-order reliability method (FORM). Our group has developed efficient spreadsheet implementation of FORM, which can be coupled with commercial software such as SLOPE/W, to handle slopes with complicated geometries and with soil nails reinforcement (Lo et al. 2022). The implementation has been applied to multiple slope cases in Hong Kong, providing practical insights on the slope reliability before and after slope improvement. Our group has also developed an efficient design chart approach to further simplify FORM analysis, which enhance reliability-based design of slopes. Utilizing the design chart approach, it is possible to reduce the amount of soil nails, at the same time improving the slope reliability.

Our group is also experienced in modelling of spatial variability of soil properties. Random field of soil properties can be simulated based on the spatial variability characteristics, which can then be applied in reliability analysis. Huang et al. (2020) coupled the conditional random field model with SLOPE/W software, with the conditional random field producing realisations that exactly match the observed data at the soil sampling locations. Lo and Leung (2017) coupled the conditional random field with finite difference modelling, to quantify the efficiency of various soil sampling strategies. Leung and Lo (2018) coupled random field model with the matrix condensation technique, which can effectively evaluate the uncertainty in differential settlement and tilting of a pile group under a superstructure loading. Mori et al. (2020) coupled the random field model with the smooth particle hydrodynamics, which can effectively evaluate the uncertainty in the runout distance during landslide.

Apart from uncertainties in loads and resistances, model uncertainty forms another important aspect in reliability analysis. Model uncertainty involves bias and randomness, where the bias indicates if the model systematically over-predicts or under-predicts the quantity in question; and the randomness indicates the variability in predictions from one prediction of that quantity to another. Our group is actively researching on characterizing and applying the model uncertainty in slope reliability analysis. This involves a through compilation of region-wide database of centrifuge slope cases, slope failure cases and soil nail pullout tests, together with probabilistic analyses on the data.

The test data serves as a valuable source on the variability of soil properties and subsurface domain, when interpreted in conjunction with the understanding of mechanics of soil and infrastructure system, could greatly assist the reliability analysis. Our group is focusing on the digitization of region-wide test database of triaxial tests and consolidation tests, which provides robust characterization on the distribution of shear strength parameters and permeability characteristics. Since a region-wide distribution may not match the distinctive site conditions, our group has formulated a hierarchical Bayesian model to narrow down the distribution of soil properties, based on the observed data of the site, in conjunction with characteristics such as particle size and site labels. Our group also is actively researching on the interpretation of region-wide test data with advanced constitutive models such as Norsand, with the aim of providing a robust distribution of model parameters for the reliability analysis of complex soil-structure interaction problems.

3. Numerical simulation in Geotechnical Engineering

Smoothed particle hydrodynamics (SPH) and its application in sinkhole formation
SPH is a mesh-free method, which was originally applied to astrophysical phenomena and was later extended to a vast range of problems in both fluid and solid mechanics. Instead of solving the governing equations on predefined grids, SPH solves the equations based on dynamic particle connections and therefore has obvious advantages in handling problems associated with large deformations and evolving free surfaces.

Undergraduate Courses

CSE 10256 Soil Mechanics

CSE 30307 Soil Mechanics for Civil Engineering

CSE 20352 Soil and Rock Engineering

Undergraduate Final Year Projects

Numerical Simulation of Sinkhole formation

Evaluation of slope process by considering the variation of water level

Corner Effects of Excavation and Lateral Support Systems

Analysis of excavation and lateral support system using nonlinear stress-strain model of Hong Kong soils

Interpretation of Inclinometer Data and Evaluation of Diaphragm Wall Behaviour

Behaviour of stone columns in clay

Seismic site response analysis for Hong Kong sites

Spatial variability of soil parameters

Back analyses of flexible retaining wall systems using optimisation methods

Professions

• President, Hong Kong Geotechnical Society (HKGES)
• Registered Professional Engineer in California, USA (No. C74029)
• Member, American Society of Civil Engineers (ASCE)
• Member, Engineering Practice of Risk Assessment and Management (TC304) (2017-present)
• Committee Member, Geotechnical Division Committee, The Hong Kong Institution of Engineers (2014 - present)
• Observer, Geotechnical Division Committee, The Hong Kong Institution of Engineers (2013 - 2014)
• Executive Committee Member, Association of Geotechnical & Geoenvironmental Specialists (Hong Kong) (2014 - present)
• Co-opt Member, Association of Geotechnical & Geoenvironmental Specialists (Hong Kong) (2013 - 2014)
• Committee Member, Technical Committee for the Code of Practice for Foundations, Buildings Department (2014 - present)
• Member, Technical Committee on Geo-engineering Education (TC306) (2015 - present)

Professional Experience 

• July 2022-Present President, Hong Kong Geotechnical Society (HKGES)
• July 2019- Present Assoicate Professor, CEE, The Hong Kong Polytechnic University
• Apr 2013 - July 2019 Assistant Professor, CEE, The Hong Kong Polytechnic University
• Jan 2011 - Mar 2013 Project Engineer, AECOM Asia Co. Ltd., Hong Kong
• Apr 2010 - Dec 2010 Geotechnical Engineer, AECOM Asia Co. Ltd., Hong Kong
• Apr 2007 & Jul 2009 Visiting Scholar, Faculty of Civil and Environmental Engineering,Technion- Israel Institute of Technology, Israel

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