open access publication

Article, 2023

Glass hardness: Predicting composition and load effects via symbolic reasoning-informed machine learning

Acta Materialia, ISSN 1873-2453, 1359-6454, Volume 255, Page 119046, 10.1016/j.actamat.2023.119046

Contributors

Mannan, Sajid 0000-0002-7887-2250 [1] Zaki, Mohd 0000-0002-4551-3470 [1] Bishnoi, Suresh 0000-0002-6736-1754 [1] Cassar, Daniel Roberto 0000-0001-6472-2780 [2] Jiusti, Jeanini 0000-0001-9923-2503 [3] Faria, Julio Cesar Ferreira [4] Christensen, Johan F S [5] Gosvami, Nitya Nand 0000-0003-4082-9887 [1] Smedskjaer, Morten Mattrup 0000-0003-0476-2021 [5] Zanotto, Edgar Dutra 0000-0003-4931-4505 (Corresponding author) [4] Krishnan, Nithiyanandan 0000-0002-5651-1008 (Corresponding author) [1]

Affiliations

  1. [1] Indian Institute of Technology Delhi
    2. [NORA names: India; Asia, South];
  2. [2] Brazilian Center for Research in Energy and Materials
    3. [NORA names: Brazil; America, South];
  3. [3] Atomic Energy and Alternative Energies Commission
    4. [NORA names: France; Europe, EU; OECD];
  4. [4] Federal University of São Carlos
    5. [NORA names: Brazil; America, South];
  5. [5] Aalborg University
    6. [NORA names: AAU Aalborg University; University; Denmark; Europe, EU; Nordic; OECD]

Abstract

Glass hardness varies in a non-linear fashion with the chemical composition and applied load, a phenomenon known as the indentation size effect (ISE), which is challenging to predict quantitatively. Here, using a curated dataset of over 3,000 inorganic glasses from the literature comprising the composition, indentation load, and hardness, we develop machine learning (ML) models to predict the composition and load dependence of Vickers hardness. Interestingly, when tested on new glass compositions unseen during the training, the standard data-driven ML model failed to capture the ISE. To address this gap, we combined an empirical expression (Bernhardt's equation) to describe the ISE with ML to develop a framework that incorporates the symbolic equation representing the domain reasoning in ML, namely Symbolic Reasoning-Informed ML Procedure (SRIMP). We show that the resulting SRIMP outperforms the data-driven ML model in predicting the ISE. Finally, we interpret the SRIMP model to understand the contribution of the glass network formers and modifiers toward composition and load-dependent (ISE) and load-independent hardness. The deconvolution of the hardness into load-dependent and load-independent terms paves the way toward a holistic understanding of the composition effect and ISE in glasses, enabling efficient and accelerated discovery of new glass compositions with targeted hardness.

Keywords

ML models, ML procedure, Vickers hardness, accelerated discovery, chemical, chemical composition, composition, composition effects, contribution, curated dataset, data-driven ML models, dataset, deconvolution, discovery, domain, domain reasoning, effect, empirical expression, equations, expression, fashion, formers, framework, gap, glass, glass composition, glass hardness, glass network formers, hardness, holistic understanding, indentation, indentation load, indentation size effect, inorganic glasses, learning, literature, load, load dependence, load effects, load-independent hardness, machine, machine learning, model, modifier, network formers, non-linear fashion, phenomenon, predicted compositions, procedure, reasons, size effect, symbolic equations, target hardness, training, understanding

Funders

  • São Paulo Research Foundation
  • Department of Science and Technology
  • European Research Council
  • Science and Engineering Research Board
  • European Union
  • National Council for Scientific and Technological Development
  • Department of Atomic Energy

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