I earned my PhD at Marquette University and then went to work at Skidmore Owings and Merrill (SOM) as a structural engineer for a number of high-profile, high-rise buildings around the world. After several years, I returned to academia by teaching at Milwaukee School of Engineering (MSOE). I continue to consult with various structural engineering companies. Over the course of my career, I have worked on teams to design structures that range from micro-scale bio-sensors to some of the tallest buildings in the world (Burj Dubai, Kunming Junfa Tower). I enjoy applying sustainable, optimization concepts to structural engineering and appreciate a hands-on, collaborative atmosphere of civil engineering. I believe strongly that “civil engineering is a people-oriented profession.”
As a structural engineer at SOM, I worked on super-tall building structural systems and innovative facades. My background and research focuses on dynamics and optimization of structural systems. I have also worked to integrate sustainability in structural use of composite materials, specifically engineered-wood and structural glass systems.
Structural Research Lab, 91³Ô¹ÏÍø University, 2016-Present
- Experimental testing of fully tempered glass for development of glass failure prediction model
- Experimental testing of cross-laminated timber (CLT) for structural characterization
- Numerical modeling and parametric studies of CLT for failure prediction
- Analytical and numerical studies of helicoidal steel beams
Structural Integration and Optimization Group, Skidmore Owings and Merrill, Chicago, 2012-2014
- Partner with architects and MEP engineers to design integrated high-rise buildings using virtual work, genetic algorithms and load path analyses methods
- Published white-paper and , “Timber Tower Research Project” funded by SLB grant
- Developed analytical sustainability tool to determine LCA of wood as a structural material
Dynamics and Mechanics Research Lab (Structures and Sensors Group), Marquette University, Milwaukee, 2009-2012
- Led investigation into the impact of Timoshenko Beam Effects and Support Compliance on Analytical Modeling of Microcantilever Frequency and Quality Factor Response for Sensors
- Performed numerical and FEA analysis using MATLAB, ANSYS and ABAQUS to determine impact of Timoshenko, geometric and material parameters on beam response
- Established a novel analytical equation for determination of quality factor for Timoshenko beams in terms of fundamental system parameters for use as sensors and energy harvesters
Structural Research Lab, Milwaukee School of Engineering, 2008-2009
- Conducted strength experiments on fully tempered, monolithic glass lites for façade applications
- Experimentally determined and numerically verified ultimate stresses and stress patterns
- Developed algorithm for FEA modeling of statically and dynamically point supported glass balustrades