Litcius/Paper detail

Dynamic Modeling of Intrinsic Self-Healing Polymers Using Deep Learning

Hashina Parveen Anwar Ali, Zichen Zhao, Yu Jun Tan, Wei Yao, Qianxiao Li, Benjamin C. K. Tee

2022ACS Applied Materials & Interfaces20 citationsDOI

Abstract

The properties of self-healing polymers are traditionally identified through destructive testing. This means that the mechanics are explored in hindsight with either theoretical derivations and/or simulations. Here, a self-healing property evolution using energy functional dynamical (SPEED) model is proposed to predict and understand the mechanics of self-healing of polymers using images of cuts dynamically healing over time. Using machine learning, an energy functional minimization (EFM) model extracted an effective underlying dynamical system from a time series of two-dimensional cut images on a self-healing polymer of constant thickness. This model can be used to capture the physics behind the self-healing dynamics in terms of potential and interface energies. When combined with a static property prediction model, the SPEED model can predict the macroscopic evolution of material properties after training only on a small set of experimental measurements. Such temporal evolutions are usually inaccessible from pure experiments or computational modeling due to the need for destructive testing. As an example, we validate this approach on toughness measurements of an intrinsic self-healing conductive polymer by capturing over 100 000 image frames of cuts to build the machine learning (ML) model. The results show that the SPEED model can be applied to predict the temporal evolution of macroscopic properties using few measurements as training data.

Topics & Concepts

Materials scienceSelf-healing materialSelf-healingComputer scienceStatistical physicsBiological systemArtificial intelligenceMechanicsPhysicsAlternative medicineMedicinePathologyBiologyFuel Cells and Related MaterialsPolymer composites and self-healingAdvanced Sensor and Energy Harvesting Materials