Related papers: Bayesian Co-navigation: Dynamic Designing of the Materials Digital Twins via Active Learning

Bayesian Co-navigation: Dynamic Designing of the Materials Digital Twins via Active Learning

URL: http://arxiv.org/abs/2404.12899v1
Date: Fri, 19 Apr 2024 14:11:32 GMT
Title: Bayesian Co-navigation: Dynamic Designing of the Materials Digital Twins via Active Learning
Authors: Boris N. Slautin, Yongtao Liu, Hiroshi Funakubo, Rama K. Vasudevan, Maxim A. Ziatdinov, Sergei V. Kalinin,
Abstract summary: Integration of theory into automated and autonomous experimental setups is emerging as a crucial objective for accelerating scientific research. Here, we introduce a method for integrating theory into the loop through Bayesian co-navigation of theoretical model space and experimentation. While demonstrated here within the context of functional responses in ferroelectric materials, our approach holds promise for broader applications.
Score: 1.1057473962658189
License: http://creativecommons.org/licenses/by-sa/4.0/
Abstract: Scientific advancement is universally based on the dynamic interplay between theoretical insights, modelling, and experimental discoveries. However, this feedback loop is often slow, including delayed community interactions and the gradual integration of experimental data into theoretical frameworks. This challenge is particularly exacerbated in domains dealing with high-dimensional object spaces, such as molecules and complex microstructures. Hence, the integration of theory within automated and autonomous experimental setups, or theory in the loop automated experiment, is emerging as a crucial objective for accelerating scientific research. The critical aspect is not only to use theory but also on-the-fly theory updates during the experiment. Here, we introduce a method for integrating theory into the loop through Bayesian co-navigation of theoretical model space and experimentation. Our approach leverages the concurrent development of surrogate models for both simulation and experimental domains at the rates determined by latencies and costs of experiments and computation, alongside the adjustment of control parameters within theoretical models to minimize epistemic uncertainty over the experimental object spaces. This methodology facilitates the creation of digital twins of material structures, encompassing both the surrogate model of behavior that includes the correlative part and the theoretical model itself. While demonstrated here within the context of functional responses in ferroelectric materials, our approach holds promise for broader applications, the exploration of optical properties in nanoclusters, microstructure-dependent properties in complex materials, and properties of molecular systems. The analysis code that supports the funding is publicly available at https://github.com/Slautin/2024_Co-navigation/tree/main

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