Learning physics from image data
Microscopy generates vast amounts of data that are crucial for advancing basic science. However, a significant gap remains between these large datasets and the discovery of underlying physical laws in complex systems like biology. With the development of quantitative, high-throughput microscopy and simulations, alongside rapid advances in data science, we are at a unique moment in time. This convergence allows us to envision learning biophysics directly from image data and enabling multiscale modeling of soft and living matter.
To achieve this goal, we use PDE-constrained optimization, Bayesian inference, and machine learning to discover continuum equations and constitutive laws (e.g. hydrodynamic equations of active matter, free energy landscape, reaction kinetics, etc.) from experimental images and molecular simulations.
Publication:
- Learning the physics of pattern formation from images Hongbo Zhao, Brian D. Storey, Richard D. Braatz, Martin Z. Bazant Physical review letters (2020) Read more
- Image Inversion and Uncertainty Quantification for Constitutive Laws of Pattern Formation Hongbo Zhao, Richard D. Braatz, Martin Z. Bazant, Journal of Computational Physics (2021) Read more
- Learning heterogeneous reaction kinetics from X-ray movies pixel-by-pixel Hongbo Zhao, Haitao Deng, Alexander Cohen, Jongwoo Lim, Yiyang Li, Dimitrios Fraggedakis, Benben Jiang, Brian D. Storey, William C. Chueh, Richard D. Braatz, Martin Z. Bazant, Nature (2023) Read more
- Correlative image learning of chemo-mechanics in phase-transforming solids
Haitao D. Deng, Hongbo Zhao, Norman Jin, Lauren Hughes, Benjamin H. Savitzky, Colin Ophus, Dimitrios Fraggedakis, András Borbély, Young-Sang Yu, Eder G. Lomeli, Rui Yan, Jueyi Liu, David A Shapiro, Wei Cai, Martin Z. Bazant, Andrew M. Minor, William C. Chueh, Nature Materials (2022) Read more
Inverse design and optimal control
Integrating differentiable physical models of soft and living matter with PDE-constrained optimization opens new avenues for the translation of basic science into practical applications in biotechnology and adaptive materials. Examples include designing microstructure via multiphase and multi-material soft matter, controlling pattern formation in active matter by engineering microscopic interactions or applying external fields like light via optogenetic control.