Micro, Nano, & Biomechanics of Materials

Biological tissue materials such as bones and muscles are commonly hierarchal complex 3D systems and their properties and functions are intrinsically linked to their underlying morphological and compositional details over a wide range of spatial scales. A combined computational and experimental approach is being used in our lab to develop advanced material models of bones that can be used to predict their basic mechanical properties as well as their complex deformation and fracture behavior.

Biological tissue materials such as bones and muscles are commonly hierarchal complex 3D systems and their properties and functions are intrinsically linked to their underlying morphological and compositional details over a wide range of spatial scales.  

Biological tissue materials such as bones and muscles are commonly hierarchal complex 3D systems and their properties and functions are intrinsically linked to their underlying morphological and compositional details over a wide range of spatial scales. A combined computational and experimental approach is being used in our lab to develop advanced material models of bones that can be used to predict their basic mechanical properties as well as their complex deformation and fracture behavior.