He, Qizhi

Assistant Professor

Contact

qzhe@umn.edu

612-624-0063

240 Civil Engineering Building
500 Pillsbury Drive SE
Minneapolis, MN 55455

He, Qizhi

Assistant Professor

Research

He Research Group

Our group works at the intersection of computational mechanics, materials modeling, and scientific machine learning, with a focus on areas that involve and advance the application of mechanics, mathematics, and numerical methods. The goal of our research is to improve fundamental understanding of multiscale materials and structures and advance the predictive simulation and design capabilities for complex engineered and natural systems. Our research interests include:

Finite element and meshfree methods for nonlinear mechanics
Machine learning enhanced computational mechanics
Data-driven mechanics
Fracture mechanics
Multiscale materials modeling
Reduced-order modeling
Subsurface flow and transport
Multi-physics modeling of geological, composite and energetic materials
Topology optimization
Musculoskeletal biomechanics
Scientific machine learning for geo-mechanics & geo-sciences
Physics-informed deep learning for inverse problems

Biography

Education

Ph.D., 2018, Structural Engineering, University of California San Diego
MA, 2016, Applied Mathematics, University of California San Diego
MS, 2013, Mechanics (Computational), Dalian University of Technology
BS, 2010, Engineering Mechanics, Wuhan University

Professional Background

Assistant Professor, University of Minnesota, 01/2022 – current
Assistant Professor of Mechanical Engineering, San Diego State University, Fall 2021
Postdoctoral Research Associate, Computational Mathematics Group, Pacific Northwest National Laboratory, 2019-2021

Teaching

Publications & Awards

Selected Publications

He, Q., Perego, M., Howard, A. A., Karniadakis, G. E., & Stinis, P. (2023). A Hybrid Deep Neural Operator/Finite Element Method for Ice-Sheet Modeling. Journal of Computational Physics, 492, 112428.

Du, H., Zhao, Z., Cheng, H., Yan, J., & He, Q. (2023). Modeling density-driven flow in porous media by physics-informed neural networks for CO2 sequestration. Computers and Geotechnics, 159, 105433.

He, X., He, Q., & Chen, J. S. (2021). Deep autoencoders for physics-constrained data-driven nonlinear materials modeling. Computer Methods in Applied Mechanics and Engineering, 385, 114034.

He, Q., & Tartakovsky, A. M. (2021). Physics‐Informed neural network method for forward and backward advection‐dispersion equations. Water Resources Research, 57(7), e2020WR029479.

Kaneko, S., Wei, H., He, Q., Chen, J. S., & Yoshimura, S. (2021). A hyper-reduction computational method for accelerated modeling of thermal cycling-induced plastic deformations. Journal of the Mechanics and Physics of Solids, 151, 104385.

He, Q., Laurence, D., Lee, C. H., Chen, J. S. (2020). Manifold learning-based data-driven modeling for soft biological tissues. Journal of Biomechanics, 110124.

He, Q., Barajas-Solano, D., Tartakovsky, G., Tartakovsky, A. (2020) Physics-Informed Neural Networks for Multiphysics Data Assimilation with Application to Subsurface Transport. Advances in Water Resources, 141, 103610.

He, Q. & Chen, J. S. (2019) A Physics-Constrained Data-Driven Approach Based on Locally Convex Reconstruction for Noisy Database. Computer Methods in Applied Mechanics and Engineering, 363, 112791.

He, Q., Chen, J. S., & Marodon, C. (2019). A decomposed subspace reduction for fracture mechanics based on the meshfree integrated singular basis function method. Computational Mechanics, 63(3), 593- 614.

He, Q., Wei, H., Chen, J. S., Wang, H. P., & Carlson, B. E. (2018). Analysis of hot cracking during lap joint laser welding processes using the melting state-based thermomechanical modeling approach. The International Journal of Advanced Manufacturing Technology, 94(9-12), 4373-4386.

He, Q., Kang, Z., & Wang, Y. (2014). A topology optimization method for geometrically nonlinear structures with meshless analysis and independent density field interpolation. Computational Mechanics, 54(3), 629-644.