Siham Kamali-Bernard scite author profile

Blended cements, where Portland cement clinker is partially replaced by supplementary cementitious materials (SCMs), provide the most feasible route for reducing carbon dioxide emissions associated with concrete production. However, lowering the clinker content can lead to an increasing risk of neutralisation of the concrete pore solution and potential reinforcement corrosion due to carbonation. carbonation of concrete with SCMs differs from carbonation of concrete solely based on Portland cement (PC). This is a consequence of the differences in the hydrate phase assemblage and pore solution chemistry, as well as the pore structure and transport properties, when varying the binder composition, age and curing conditions of the concretes. The carbonation mechanism and kinetics also depend on the saturation degree of the concrete and CO2 partial pressure which in turn depends on exposure conditions (e.g. relative humidity, volume, and duration of water in contact with the concrete surface and temperature conditions). This in turn influence the microstructural changes identified upon carbonation. This literature review, prepared by members of RILEM technical committee 281-CCC carbonation of concrete with supplementary cementitious materials, working groups 1 and 2, elucidates the effect of numerous SCM characteristics, exposure environments and curing conditions on the carbonation mechanism, kinetics and structural alterations in cementitious systems containing SCMs.

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Design of new blended cement based on marine dredged sediment

Dang

Kamali-Bernard

Prince

2013

Construction and Building Materials

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3D multi-scale modelling of mechanical behaviour of sound and leached mortar

Bernard¹,

Kamali-Bernard²,

Prince³

2008

Cement and Concrete Research

110

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Numerical study of ITZ contribution on mechanical behavior and diffusivity of mortars

Bernard

Kamali-Bernard

2015

Computational Materials Science

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Ground Granulated Blast-Furnace Slag

Matthes¹,

Vollpracht

Villagrán

et al. 2017

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Since the discovery of the latent hydraulic reactivity of ground granulated blast-furnace slag (ggbfs) by Emil Langen at the end of the 19th century, this material has been used successfully as cement and concrete addition. This chapter includes all relevant information about this valuable material-from production and processing to the effect, which ggbfs additions have on the concrete performance. In this context, light is shed on decisive performance parameters of ggbfs. Of special interest nowadays is certainly also the information given about trace element contents in ggbfs and their leachability. Here and throughout the entire chapter, the latest insights from research and development work are included. Last but not least, the chapter contains very practical information when it comes to the use of ggbfs in concrete, including insights on rheological effects, concrete color and "greening", and adequate curing. Moreover, an overview about relevant norms and standards on ggbfs as concrete addition is given.

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Durability of self-compacting concrete containing pumice and zeolite against acid attack, carbonation and marine environment

Samimi

Kamali-Bernard

Maghsoudi

2018

Construction and Building Materials

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