Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems

Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems

Abstract Carbonaceous (e.g., limestone) and aluminosilicate (e.g., calcined clay) mineral additives are routinely used to partially replace ordinary portland cement in concrete to alleviate its energy impact and carbon footprint. These mineral additives—depending on their physicochemical characteris...

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Main Authors: Jonathan Lapeyre, Taihao Han, Brooke Wiles, Hongyan Ma, Jie Huang, Gaurav Sant, Aditya Kumar
Format: Article
Language:English
Published: Nature Publishing Group 2021-02-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-83582-6
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spelling doaj-2b8f2c49536b4819adcd2cd461f2d5002021-02-21T12:31:14ZengNature Publishing GroupScientific Reports2045-23222021-02-0111111610.1038/s41598-021-83582-6Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systemsJonathan Lapeyre0Taihao Han1Brooke Wiles2Hongyan Ma3Jie Huang4Gaurav Sant5Aditya Kumar6Materials Science and Engineering, Missouri University of Science and TechnologyMaterials Science and Engineering, Missouri University of Science and TechnologyMaterials Science and Engineering, Missouri University of Science and TechnologyCivil, Architectural and Environmental Engineering, Missouri University of Science and TechnologyElectrical and Computer Engineering, Missouri University of Science and TechnologyCivil and Environmental Engineering, University of CaliforniaMaterials Science and Engineering, Missouri University of Science and TechnologyAbstract Carbonaceous (e.g., limestone) and aluminosilicate (e.g., calcined clay) mineral additives are routinely used to partially replace ordinary portland cement in concrete to alleviate its energy impact and carbon footprint. These mineral additives—depending on their physicochemical characteristics—alter the hydration behavior of cement; which, in turn, affects the evolution of microstructure of concrete, as well as the development of its properties (e.g., compressive strength). Numerical, reaction-kinetics models—e.g., phase boundary nucleation-and-growth models; which are based partly on theoretically-derived kinetic mechanisms, and partly on assumptions—are unable to produce a priori prediction of hydration kinetics of cement; especially in multicomponent systems, wherein chemical interactions among cement, water, and mineral additives occur concurrently. This paper introduces a machine learning-based methodology to enable prompt and high-fidelity prediction of time-dependent hydration kinetics of cement, both in plain and multicomponent (e.g., binary; and ternary) systems, using the system’s physicochemical characteristics as inputs. Based on a database comprising hydration kinetics profiles of 235 unique systems—encompassing 7 synthetic cements and three mineral additives with disparate physicochemical attributes—a random forests (RF) model was rigorously trained to establish the underlying composition-reactivity correlations. This training was subsequently leveraged by the RF model: to predict time-dependent hydration kinetics of cement in new, multicomponent systems; and to formulate optimal mixture designs that satisfy user-imposed kinetics criteria.https://doi.org/10.1038/s41598-021-83582-6
collection DOAJ
language English
format Article
sources DOAJ
author Jonathan Lapeyre
Taihao Han
Brooke Wiles
Hongyan Ma
Jie Huang
Gaurav Sant
Aditya Kumar
spellingShingle Jonathan Lapeyre
Taihao Han
Brooke Wiles
Hongyan Ma
Jie Huang
Gaurav Sant
Aditya Kumar
Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
Scientific Reports
author_facet Jonathan Lapeyre
Taihao Han
Brooke Wiles
Hongyan Ma
Jie Huang
Gaurav Sant
Aditya Kumar
author_sort Jonathan Lapeyre
title Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
title_short Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
title_full Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
title_fullStr Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
title_full_unstemmed Machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
title_sort machine learning enables prompt prediction of hydration kinetics of multicomponent cementitious systems
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-02-01
description Abstract Carbonaceous (e.g., limestone) and aluminosilicate (e.g., calcined clay) mineral additives are routinely used to partially replace ordinary portland cement in concrete to alleviate its energy impact and carbon footprint. These mineral additives—depending on their physicochemical characteristics—alter the hydration behavior of cement; which, in turn, affects the evolution of microstructure of concrete, as well as the development of its properties (e.g., compressive strength). Numerical, reaction-kinetics models—e.g., phase boundary nucleation-and-growth models; which are based partly on theoretically-derived kinetic mechanisms, and partly on assumptions—are unable to produce a priori prediction of hydration kinetics of cement; especially in multicomponent systems, wherein chemical interactions among cement, water, and mineral additives occur concurrently. This paper introduces a machine learning-based methodology to enable prompt and high-fidelity prediction of time-dependent hydration kinetics of cement, both in plain and multicomponent (e.g., binary; and ternary) systems, using the system’s physicochemical characteristics as inputs. Based on a database comprising hydration kinetics profiles of 235 unique systems—encompassing 7 synthetic cements and three mineral additives with disparate physicochemical attributes—a random forests (RF) model was rigorously trained to establish the underlying composition-reactivity correlations. This training was subsequently leveraged by the RF model: to predict time-dependent hydration kinetics of cement in new, multicomponent systems; and to formulate optimal mixture designs that satisfy user-imposed kinetics criteria.
url https://doi.org/10.1038/s41598-021-83582-6
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