Conducts research and experimental testing with the following equipment:<br>240-ton double action hydraulic press for blanking, piercing, formability testing (Nakazima, Marciniak, Erichsen, bending, hole expansion, hydraulic bulge test), cyclic shear, hot stamping, die wear testing, etc.<br> <br>Tension/compression split Hopkinson bar apparatus for high strain rate characterization of work hardening behaviour of metals<br>Flat rolling mill for pre-straining up to large deformations<br>Instron Charpy impact tester for fracture toughness<br>Metallurgical lab, optical microscope, scanning electron microscope <br>FMTI optical strain measurement, high-resolution stereo-cameras, high-speed Photron cameras with digital image correlation software<br>Performs Numerical simulations including finite element simulations of various metal forming processes (stamping, drawing, springback prediction, hydroforming, piercing, trimming, electrohydraulic forming etc.) using LS-Dyna or ABAQUS. <br>Development of user-defined material subroutines for ABAQUS allows advanced constitutive models and damage models to be used that are not commercially available.<br><br>Engages in constitutive and damage modeling such as the development of advanced anisotropic, rate-dependent constitutive models and ductile damage models for use in finite element simulations and for prediction of forming behaviour, of the onset of plastic instability and fracture.<br><br>Carries out micromechanical modeling: development of micro- and mesoscale mechanical models (RVE representative volume element, CA cellular automata) for prediction of deformation and fracture of multi-phase steel sheets.