Abstract
Alkali-activated binders (AAB) can provide a clean alternative to conventional cement in terms of CO2 emissions. However, as yet there are no sufficiently accurate material models to effectively predict the AAB properties, thus making optimal mix design highly costly and reducing the attractiveness of such binders. This work adopts sequential learning (SL) in high-dimensional material spaces (consisting of composition and processing data) to find AABs that exhibit desired properties. The SL approach combines machine learning models and feedback from real experiments. For this purpose, 131 data points were collected from different publications. The data sources are described in detail, and the differences between the binders are discussed. The sought-after target property is the compressive strength of the binders after 28 days. The success is benchmarked in terms of the number of experiments required to find materials with the desired strength. The influence of some constraints was systematically analyzed, e.g., the possibility to parallelize the experiments, the influence of the chosen algorithm and the size of the training data set. The results show the advantage of SL, i.e., the amount of data required can potentially be reduced by at least one order of magnitude compared to traditional machine learning models, while at the same time exploiting highly complex information. This brings applications in laboratory practice within reach.
Highlights
Concrete is the most widely used building material on earth
We argue for including much more detailed information in Machine Learning (ML) models and showed how useful material models can still be generated with very few data sets
The results show that the discovery of new precursors for construction binders can be accelerated using sequential learning (SL)
Summary
Concrete is the most widely used building material on earth. In 2019 alone, worldwide 30 billion tons of concrete was produced—that is almost four tons for every single person [1]. If the climate agreements are adhered to, the question arises as to what extent ordinary Portland cement (OPC) as a building material is still viable as a mass product [3]. In this regard, the cement technology roadmap defined several ways to reduce the CO2 footprint at every step of cement production and huge afford has been made to develop more environmentally friendly binders [4]. Alkali-activated binders (AAB) and/or geopolymers (GP) omit the energy-intensive kiln process that is responsible for a large part of the CO2 emissions of conventional types of cement and are considered as environmentally friendly alternatives [6]
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