Pore Network Modelling
CFD Simulation
In nature, the meniscus acts as a biological shock absorber. To understand how it dissipates energy, we applied image-based Computational Fluid Dynamics (CFD) techniques to simulate how fluid moves through its intricate internal architecture.
Showcase fluid simulation
Detailed CFD results of Re along specific channels
Showcase fluid simulation
Fractional Poroelasticity
Fractional Poroelasticity combines poroelastic theory with functional calculus. Since soft tissues are not purely elastic, they show complex time-dependent responses and traditional poroelastic models may oversimplify these responses.
The figure below shows that the pore pressure field predictions are considerably different between fractional and classical Biot theory. Click below to read further.
Image-Based Multi-Physics Modelling.
Multi-physics modelling combines diffusion and mechanics to simulate real-world materials' behaviour under complex conditions. When powered by image-based geometry, simulations gain biological or material accuracy, capturing microstructural features directly from imaging techniques like TEM or SEM.
Plots showing the evolution of hydrogen-induced softening and deformation
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