Carbonation, strength development, and characterization of calcined limestone as a potential construction material

Rotana Hay; Ghanim Kashwani; Kemal Celik

doi:10.1016/j.cemconres.2020.106263

Carbonation, strength development, and characterization of calcined limestone as a potential construction material

Rotana Hay, Ghanim Kashwani, Kemal Celik

Research output: Contribution to journal › Article › peer-review

Abstract

The emergence of the modern Portland cement has led to the downfall of lime as a construction material. Consequentially, its use has been limited to repair and restoration of historical buildings. Yet, its lower calcination temperature (~950 °C) and the ability to gain strength through carbonation implies its potential as a sustainable alternative to cement. In this study, calcined limestone was studied concerning its carbonation and strength development. Superplasticizer, raw limestone, and different carbonation regimes were explored as techniques to improve the composite strength development, a shortfall that hinders its re-adoption. The results indicated that the raw limestone as a partial replacement of the calcined limestone significantly improved the carbonation degree and mechanical properties. The average compressive strength reached 20 MPa under 20% CO ₂ due to the formation of an interconnected network of calcite as the dominant carbonation product. Supercritical CO ₂, in contrast, formed disjoint particles or agglomerates of carbonates.

Original language	English (US)
Article number	106263
Journal	Cement and Concrete Research
Volume	139
DOIs	https://doi.org/10.1016/j.cemconres.2020.106263
State	Published - Jan 2021

Keywords

CO sequestration
Calcined limestone
Calcium carbonate
Carbonation
Supercritical CO

ASJC Scopus subject areas

Building and Construction
Materials Science(all)

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10.1016/j.cemconres.2020.106263

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title = "Carbonation, strength development, and characterization of calcined limestone as a potential construction material",

abstract = "The emergence of the modern Portland cement has led to the downfall of lime as a construction material. Consequentially, its use has been limited to repair and restoration of historical buildings. Yet, its lower calcination temperature (~950 °C) and the ability to gain strength through carbonation implies its potential as a sustainable alternative to cement. In this study, calcined limestone was studied concerning its carbonation and strength development. Superplasticizer, raw limestone, and different carbonation regimes were explored as techniques to improve the composite strength development, a shortfall that hinders its re-adoption. The results indicated that the raw limestone as a partial replacement of the calcined limestone significantly improved the carbonation degree and mechanical properties. The average compressive strength reached 20 MPa under 20% CO 2 due to the formation of an interconnected network of calcite as the dominant carbonation product. Supercritical CO 2, in contrast, formed disjoint particles or agglomerates of carbonates. ",

keywords = "CO sequestration, Calcined limestone, Calcium carbonate, Carbonation, Supercritical CO",

author = "Rotana Hay and Ghanim Kashwani and Kemal Celik",

note = "Funding Information: The authors thank the NYUAD Center for Interacting Urban Networks (CITIES), funded by Tamkeen under the NYUAD Research Institute Award CG001 and by the Swiss Re Institute under the Quantum Cities{\texttrademark} initiative for providing financial support to make this research possible. This research was also partially carried out using the Core Technology Platforms (CTPs) resources at New York University Abu Dhabi, and the assistance provided by Dr. James Weston and Dr. Liang Li of CTPs is greatly appreciated. We would also like to acknowledge our undergraduate student Cornelius Otchere for his help with some of the experimental works. Publisher Copyright: {\textcopyright} 2020 Elsevier Ltd",

year = "2021",

month = jan,

doi = "10.1016/j.cemconres.2020.106263",

language = "English (US)",

volume = "139",

journal = "Cement and Concrete Research",

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AU - Hay, Rotana

AU - Kashwani, Ghanim

AU - Celik, Kemal

N1 - Funding Information: The authors thank the NYUAD Center for Interacting Urban Networks (CITIES), funded by Tamkeen under the NYUAD Research Institute Award CG001 and by the Swiss Re Institute under the Quantum Cities™ initiative for providing financial support to make this research possible. This research was also partially carried out using the Core Technology Platforms (CTPs) resources at New York University Abu Dhabi, and the assistance provided by Dr. James Weston and Dr. Liang Li of CTPs is greatly appreciated. We would also like to acknowledge our undergraduate student Cornelius Otchere for his help with some of the experimental works. Publisher Copyright: © 2020 Elsevier Ltd

PY - 2021/1

Y1 - 2021/1

N2 - The emergence of the modern Portland cement has led to the downfall of lime as a construction material. Consequentially, its use has been limited to repair and restoration of historical buildings. Yet, its lower calcination temperature (~950 °C) and the ability to gain strength through carbonation implies its potential as a sustainable alternative to cement. In this study, calcined limestone was studied concerning its carbonation and strength development. Superplasticizer, raw limestone, and different carbonation regimes were explored as techniques to improve the composite strength development, a shortfall that hinders its re-adoption. The results indicated that the raw limestone as a partial replacement of the calcined limestone significantly improved the carbonation degree and mechanical properties. The average compressive strength reached 20 MPa under 20% CO 2 due to the formation of an interconnected network of calcite as the dominant carbonation product. Supercritical CO 2, in contrast, formed disjoint particles or agglomerates of carbonates.

AB - The emergence of the modern Portland cement has led to the downfall of lime as a construction material. Consequentially, its use has been limited to repair and restoration of historical buildings. Yet, its lower calcination temperature (~950 °C) and the ability to gain strength through carbonation implies its potential as a sustainable alternative to cement. In this study, calcined limestone was studied concerning its carbonation and strength development. Superplasticizer, raw limestone, and different carbonation regimes were explored as techniques to improve the composite strength development, a shortfall that hinders its re-adoption. The results indicated that the raw limestone as a partial replacement of the calcined limestone significantly improved the carbonation degree and mechanical properties. The average compressive strength reached 20 MPa under 20% CO 2 due to the formation of an interconnected network of calcite as the dominant carbonation product. Supercritical CO 2, in contrast, formed disjoint particles or agglomerates of carbonates.

KW - CO sequestration

KW - Calcined limestone

KW - Calcium carbonate

KW - Carbonation

KW - Supercritical CO

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Carbonation, strength development, and characterization of calcined limestone as a potential construction material

Abstract

Keywords

ASJC Scopus subject areas

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