Comparative environmental footprint analysis of ultra-high-performance concrete using Portland cement and alkali-activated materials

Glanz, Dilan; Sameer, Husam; Göbel, Daniela; Wetzel, Alexander; Middendorf, Bernhard; Mostert, Clemens; Bringezu, Stefan

doi:10.3389/fbuil.2023.1196246

Cited by 9 publications

(1 citation statement)

References 30 publications

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“…Reducing the use of cement thus reduces emissions. This can be achieved by the addition of supplementary cementitious materials (SCM) to cement, or by using alternatives where the cement is fully substituted entirely by latent hydraulic or pozzolanic binders or by using alkali activated materials (AAM) [2] or geopolymers [3] which can reduce the climate footprint [4][5][6]. Additional, by increasing the performance of the cement paste matrix, the cement content can also be reduced with consistent properties.…”

Section: Introductionmentioning

confidence: 99%

Spatially resolved in situ analyses of the adsorption behavior of different admixtures on binders

Kosenko,

Wetzel,

Middendorf

2023

ce papers

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Admixtures play a key role in improving the performance of the cement paste matrix. A more efficient matrix can allow a reduction the binder content while maintaining the same properties. There is currently a lack of knowledge about the spatial distribution of admixtures in situ on binder surfaces which would facilitate the use of admixtures in general in inorganic binder systems. Imaging techniques such as confocal laser scanning microscopy (CLSM) and fluorescence microscopy can be used to study the spatiotemporal adsorption of superplasticizers and plasticizers on binder particles. However, in order to make the admixtures visible using these methods, they must first be coupled to a fluorescent molecule (staining). Different types of superplasticizers and plasticizers, including polycarboxylate ethers (PCE) and lignosulfonate (LS) were stained and tested. It was shown that not only adsorption but also desorption can be observed and that desorption cannot play a relevant role in a binder system. The absence of desorption could be used to observe a real system in permanent preparations, so that the adsorption on individual cement grains could be followed in a time‐dependent manner. The newly developed method provides unprecedented insight into the adsorption of additives.

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Section: Introductionmentioning

confidence: 99%

Spatially resolved in situ analyses of the adsorption behavior of different admixtures on binders

Kosenko,

Wetzel,

Middendorf

2023

ce papers

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The influence of phase change material filled three-dimensional printed artificial aggregates on the properties of blast furnace slag based alkali-activated concrete

Omur,

Akpunar,

Bingöl

et al. 2025

Front. Struct. Civ. Eng.

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Active learning on stacked machine learning techniques for predicting compressive strength of alkali-activated ultra-high-performance concrete

Kazemi,

Shafighfard,

Jankowski

et al. 2024

Arch. Civ. Mech. Eng.

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Conventional ultra-high performance concrete (UHPC) has excellent development potential. However, a significant quantity of CO2 is produced throughout the cement-making process, which is in contrary to the current worldwide trend of lowering emissions and conserving energy, thus restricting the further advancement of UHPC. Considering climate change and sustainability concerns, cementless, eco-friendly, alkali-activated UHPC (AA-UHPC) materials have recently received considerable attention. Following the emergence of advanced prediction techniques aimed at reducing experimental tools and labor costs, this study provides a comparative study of different methods based on machine learning (ML) algorithms to propose an active learning-based ML model (AL-Stacked ML) for predicting the compressive strength of AA-UHPC. A data-rich framework containing 284 experimental datasets and 18 input parameters was collected. A comprehensive evaluation of the significance of input features that may affect compressive strength of AA-UHPC was performed. Results confirm that AL-Stacked ML-3 with accuracy of 98.9% can be used for different general experimental specimens, which have been tested in this research. Active learning can improve the accuracy up to 4.1% and further enhance the Stacked ML models. In addition, graphical user interface (GUI) was introduced and validated by experimental tests to facilitate comparable prospective studies and predictions.

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Comparative environmental footprint analysis of ultra-high-performance concrete using Portland cement and alkali-activated materials

Cited by 9 publications

References 30 publications

Spatially resolved in situ analyses of the adsorption behavior of different admixtures on binders

Spatially resolved in situ analyses of the adsorption behavior of different admixtures on binders

The influence of phase change material filled three-dimensional printed artificial aggregates on the properties of blast furnace slag based alkali-activated concrete

Active learning on stacked machine learning techniques for predicting compressive strength of alkali-activated ultra-high-performance concrete

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