Exploring advanced research and software development in geomechanics and hydrogeology.
A comprehensive investigation into the hydro-mechanical behavior of fractured media, using numerical simulations to understand the impacts on fluid flow and structural integrity.
Developing advanced methods for site modeling and discrete fracture network (DFN) generation to support geological assessments and engineering applications.
Using genetic algorithms to optimize the generation of discrete fracture networks for more accurate geological modeling and simulation.
Exploring flow and transport phenomena in site models to enhance our understanding of fluid movement in fractured rock formations.
This project investigates the hydro-mechanical behavior of fractured media, focusing on how fractures influence both the mechanical stability of rock and fluid flow. Using advanced numerical simulations, the project explores the coupled effects between fluid movement and mechanical deformation, providing insights for applications in geotechnical engineering and natural resource management.
For more information, visit the full project page: Hydro-Mechanical Effects in Fractured Media
This project focuses on the development of advanced methods for site modeling and discrete fracture network (DFN) generation. These techniques are essential for supporting geological assessments and engineering applications by providing realistic representations of fractured rock systems.
For more information, visit the full project page: Site Modelling and DFN Generation
This project uses genetic algorithms to optimize the generation of discrete fracture networks, improving geological modeling and simulation accuracy. The use of genetic algorithms allows for efficient exploration of fracture network configurations, leading to more realistic geological assessments.
For more information, visit the full project page: Genetic Discrete Fracture Networks
This project investigates flow and transport phenomena in geological site models, enhancing our understanding of fluid movement within fractured rock formations. The findings contribute to improving predictions for natural resource management and environmental safety.
For more information, visit the full project page: Site Modelling for Flow and Transport