In general, the goal of our research group is to characterize the behavior of novel and classical structures and materials and derive mathematical models and/or simulation tools that accurately reflect the observed behavior of these materials and structures from fundamental principles. These models can be used to design and analyze systems under a wide array of loading conditions. Accurate and reliable models for the behavior of materials and structures are increasingly important as engineers have more computational power and thus can analyze more complex conditions, but such analyses are only as good as the underlying model and our understanding of the material behavior. Better understanding and predictions can lead to safer, cheaper, more reliable, and more efficient design of structures and machines. Research projects are constantly evolving, however, below are a few examples of current research projects in our group.


Plasticity

Plastic deformation occurs when a material is loaded beyond the elastic limit, and it is especially difficult to predict because it is highly non-linear and history dependent. We are currently using the models for yield surface distortion to try to improve predictions of multi-axial ratcheting, the accumulation of plastic deformation due to cyclic plastic loading. Predicting ratcheting is especially difficult because any small errors in one cycle accumulate over several cycles, and predicting ratcheting is especially important to foresee and prevent material failure in any structure subject to earthquakes, extreme weather, and/or cyclic mechanical and thermal service conditions.

   

Artificial Muscles

Artificial muscle systems have the potential to impact industries ranging from advanced prosthesis to miniature robotics. Our group is currently developing and experimentally validating analytic models of novel, low cost, high power twisted polymer actuators that can serve as artificial muscles. The challenges associated with developing this model include the asymmetric nature of the material, the complex twisted geometry, and temperature and load variations. This research is being performed in conjunction with the Dynamic and Active Systems Lab (DASL).

   

Magnetic Shape Memory Alloys

Magnetic shape memory alloys (MSMAs) can undergo a recoverable deformation in the presence of a magnetic field or mechanical load as internal martensitic variants reorient. The deformation can be recovered by a magnetic field and/or mechanical load in an orthogonal direction. Our group has developed several thermodynamic based models to predict the magneto-mechanical behavior of MSMAs, the most recent of which is fully three-dimensional. While this model predicts general trends, it is lacking accuracy, so we are currently trying decipher what the model is lacking and how it can be improved. This research is being performed in conjunction with the Multifunctional Materials and Adaptive Systems Lab.