Related papers: Deep learning for synthetic microstructure generation in a materials-by-design framework for heterogeneous energetic materials

Deep learning for synthetic microstructure generation in a materials-by-design framework for heterogeneous energetic materials

URL: http://arxiv.org/abs/2004.04814v1
Date: Sun, 5 Apr 2020 16:58:31 GMT
Title: Deep learning for synthetic microstructure generation in a materials-by-design framework for heterogeneous energetic materials
Authors: Sehyun Chun, Sidhartha Roy, Yen Thi Nguyen, Joseph B. Choi, H.S. Udaykumar, Stephen S. Baek
Abstract summary: Multi-scale predictive models of chemical reactions account for the physics at the meso-scale. Meso-scale physics is infused in machine-learned closure models informed by resolved meso-scale simulations. We propose utilizing generative adversarial networks (GAN) to spawn ensembles of synthetic heterogeneous energetic material microstructures.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The sensitivity of heterogeneous energetic (HE) materials (propellants, explosives, and pyrotechnics) is critically dependent on their microstructure. Initiation of chemical reactions occurs at hot spots due to energy localization at sites of porosities and other defects. Emerging multi-scale predictive models of HE response to loads account for the physics at the meso-scale, i.e. at the scale of statistically representative clusters of particles and other features in the microstructure. Meso-scale physics is infused in machine-learned closure models informed by resolved meso-scale simulations. Since microstructures are stochastic, ensembles of meso-scale simulations are required to quantify hot spot ignition and growth and to develop models for microstructure-dependent energy deposition rates. We propose utilizing generative adversarial networks (GAN) to spawn ensembles of synthetic heterogeneous energetic material microstructures. The method generates qualitatively and quantitatively realistic microstructures by learning from images of HE microstructures. We show that the proposed GAN method also permits the generation of new morphologies, where the porosity distribution can be controlled and spatially manipulated. Such control paves the way for the design of novel microstructures to engineer HE materials for targeted performance in a materials-by-design framework.

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