Relate atomic scale interactions, type(s) of bonding, crystallinity, impurities, processing history in a material to structure and properties of the material that are observed at the macroscopic scale
Describe long-range order and short-range order; and use fundamental concepts such as primitive vectors, translational symmetry, Miller indices, and characterization tools (i.e., x-ray spectroscopy) to calculate parameters that are used to define long-range order in materials
Relate quantitatively and qualitatively flux, diffusion constant, time and temperature to each other and predict the outcomes of possible scenarios in materials science based on diffusion behavior in materials
Verbally define Young?s Modulus, yield stress, toughness, ductility, ultimate tensile stress, resilience, fracture toughness and show how to relate and calculate these terms for different cases
Draw the band structure of metals, polymers and semi-conductors, state quantitatively and qualitatively how the charge carriers, their mobility, and temperature affect conductivity in these materials
Interrelate the mechanical, thermal, and electrical properties of materials
Explain phase behavior and how thermodynamics and kinetics may be used to manipulate the observed phases
|