PiezoTensorNet: Crystallography informed multi-scale hierarchical machine learning model for rapid piezoelectric performance finetuning

Piezoelectric devices offer numerous opportunities for sustainable harvesting of wasted mechanical energy, leading to a significant interest in data-driven research on these materials. This study presents the design of PiezoTensorNet, a comprehensive framework that encompasses a hierarchical classif...

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Bibliographic Details
Published in:Applied energy 2024-05, Vol.361, p.122901, Article 122901
Main Authors: Poudel, Sachin, Thapa, Rubi, Basnet, Rabin, Timofiejczuk, Anna, Kunwar, Anil
Format: Article
Language:English
Subjects:
Automatic Control Engineering
Computer Science
Crystal rotation
Electromechanical finetuning
Energy conversion
Engineering Sciences
Materials
Mechanical engineering
Mechanics
Piezoelectric tensors
Quasi-effective coefficients
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Summary:Piezoelectric devices offer numerous opportunities for sustainable harvesting of wasted mechanical energy, leading to a significant interest in data-driven research on these materials. This study presents the design of PiezoTensorNet, a comprehensive framework that encompasses a hierarchical classification neural network for crystal point group determination and modular ensembles of regression-based multi-dimensional models for predicting piezoelectric tensors. The machine learning models capable of forecasting tensors for dopant element alloying and various crystallographic transformations is integrated along with finite element analysis for electromechanical performance evaluation. The efficacy of integrated toolkit is demonstrated through the computational design and discovery of a lead-free microelectromechanical system based on AlN. The introduction of Boron and Erbium dopants in AlN enhances its piezoelectric performance, particularly when the crystal undergoes rotations along a preferred axis. Specifically, under a vertical loading of 5 × 10−5 N/m2 applied to a cantilever beam, the preferentially oriented B0.3Er0.5Al0.2N material generates a power 9.96 times larger than that of AlN ceramics. [Display omitted] •Crystallography informed machine learning models.•Composition-based feature vector for allowing the entry of dopant elements of different amount.•PiezoTensorNet able to design materials with quasi-effective piezoelectric coefficients.•Crystal-rotated B0.3Er0.5Al0.2N alloy has larger piezoelectric response than AlN ceramic.•PiezoTensorNet web app released online.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2024.122901