CemGEMS – an easy-to-use web application for thermodynamic modeling of cementitious materials

Kulik, Dmitrii A.; Winnefeld, Frank; Кулик, А. В.; Miron, George Dan; Lothenbach, Barbara

doi:10.21809/rilemtechlett.2021.140

Cited by 36 publications

(15 citation statements)

References 76 publications

(135 reference statements)

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“…Thermodynamic modeling is conducted by using the GEMS v3.9 program to imitate the phase change of UHCP in CO 2 solution at 5°C based on the CEMDATA18 (Kulik 2002;Wagner et al 2012;Lothenbach et al 2019;Kulik et al 2021). The data include cementitious system production and different of composition of C-S-H phases; this calculation used the CSHQ model from Kulik (2011) and Shi et al (2016).…”

Section: Appendix A-1mentioning

confidence: 99%

Wet-carbonation-based Mineral Extraction and CO<sub>2</sub> Sequestration Using Concrete Waste Fines at a Low Temperature

Bui

Kurihara

Wang

et al. 2023

ACT

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This study investigates the wet carbonation of concrete fines with CO 2 and natural air gas bubbling in a carbonation system at low temperatures. After the air-and CO 2 -wet carbonations, the properties of a solution and hydrated cement paste powder are determined. In the air and CO 2 -wet carbonations, more Ca is extracted into the solution at a low temperature of 5°C. This high Ca concentration in the solution through air-wet carbonation primarily originates from the portlandite and unhydrated phases of the cement paste. Even in solutions with high pH values, the rehydration process and C-S-H decomposition occur simultaneously in air-wet carbonation. Moreover, CO 2 -wet carbonation indicates that the decalcification of C-S-H occurs rapidly, even in the presence of portlandite. Air-wet carbonation presents a potential method for the direct air capture of CO 2 using concrete waste fines in a short period.

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Section: Appendix A-1mentioning

confidence: 99%

Wet-carbonation-based Mineral Extraction and CO<sub>2</sub> Sequestration Using Concrete Waste Fines at a Low Temperature

Bui

Kurihara

Wang

et al. 2023

ACT

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“…where DoR is the reaction degree, t is the hydration time in days, a is the minimum reaction degree (set to 0), B is the maximum steepness, c is the inflection point and d is the maximum reaction degree (set to 100) [47,48]. All thermodynamic calculations were conducted at 20 °C under oxidizing conditions.…”

Section: Thermodynamic Modellingmentioning

confidence: 99%

The influence of calcium sulfate content on the hydration of belite-calcium sulfoaluminate cements with different clinker phase compositions

et al. 2021

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The influence of different amounts of gypsum on the hydration of a belite-rich and a ye'elimite-rich belite-calcium sulfoaluminate clinker (BCSA) was investigated. The hydration kinetics, phase assemblages and compressive strength development of cements prepared using ye’elimite/ calcium sulfate molar ratios of 1, 1.5 and 2 were studied. Besides ettringite and monosulfate, aluminium hydroxide, strätlingite, C−S−H, iron-containing siliceous hydrogarnet and hydrotalcite were present as hydration products. Increasing the amount of gypsum increased the ratio of ettringite to monosulfate formed in the cement paste, lowered the amount of pore solution, delayed the dissolution of belite and ferrite, decreased the formation of strätlingite and, in the case of the ye’elimite-rich BCSA, led to an increase in compressive strength. Increased amounts of belite in the clinker led to the formation of higher quantities of C–S–H, at the expense of strätlingite and a lower compressive strength, as belite has a lower degree of reaction than ye’elimite and due to the formation of more C–S–H and strätlingite compared to the more space-filling ettringite. The thermodynamic model established for BCSA cement hydration agrees well with the experimental data. Compressive strength directly correlated with bound water from thermogravimetric analyses and inversely correlated with the porosity calculated from thermodynamic modelling.

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“…40% or Portland cement by calcined clay, 2 there is potential market for >1.5 Gt of calcined clay annually in the cement industry alone. Emerging cementitious systems/technologies using calcined clay, such as the limestone-calcined claycement blends known as LC 3 , 2 have already proven to be suitable for wide scale adoption, based on experimental testing of the cement and concrete performance. However, there is little systematic understanding of how the thermodynamic properties of clays (raw and calcined) and their solid solutions or associated minerals (linked to their origin) will affect the production/calcination process (including interaction with process atmosphere) and their reactivity and performance in cementitious binders.…”

Section: Introductionmentioning

confidence: 99%

“…Fortunately, the advancement of computing technology/power makes thermodynamic calculations much more accessible, and potentially also sufficiently user-friendly to enable their direct use in cementitious materials design. 3,4…”

Section: Introductionmentioning

confidence: 99%

Thermodynamics of calcined clays used in cementitious binders: origin to service life considerations

Hanein¹,

Nguyen²,

Provis³

et al. 2023

J. Mater. Chem. A

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CemGEMS – an easy-to-use web application for thermodynamic modeling of cementitious materials

Cited by 36 publications

References 76 publications

Wet-carbonation-based Mineral Extraction and CO<sub>2</sub> Sequestration Using Concrete Waste Fines at a Low Temperature

Wet-carbonation-based Mineral Extraction and CO<sub>2</sub> Sequestration Using Concrete Waste Fines at a Low Temperature

The influence of calcium sulfate content on the hydration of belite-calcium sulfoaluminate cements with different clinker phase compositions

Thermodynamics of calcined clays used in cementitious binders: origin to service life considerations

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