Modelagem termodinâmica de pastas de cimento Portland expostas a sulfato de sódio e sulfato de magnésio

Igor Rossi Remenche; Diego Jesus De Souza; André Luiz Pereira Vizzotto; Marcelo Henrique Farias de Medeiros; Juarez Hoppe Filho; Eduardo Pereira

doi:10.1590/s1678-86212026000100962

Modelagem termodinâmica de pastas de cimento Portland expostas a sulfato de sódio e sulfato de magnésio

Translated title of the contribution: Thermodynamic modeling of Portland cement pastes exposed to sodium sulfate and magnesium sulfate

Igor Rossi Remenche^*
, Diego Jesus De Souza
, André Luiz Pereira Vizzotto
, Marcelo Henrique Farias de Medeiros
, Juarez Hoppe Filho
, Eduardo Pereira

^*Corresponding author for this work

Universidade Federal do Paraná
Universidade Tecnológica Federal do Paraná
Universidade Federal do Oeste da Bahia
Universidade Estadual de Ponta Grossa

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

Sulfate attack in concrete structural elements can lead to the precipitation of expansive products, such as ettringite and gypsum, compromising the service life and durability of the material. This study aimed to investigate, through mineralogical (XRD) and thermal (TG/DTG) analyses combined with thermodynamic modeling, the behavior of two paste compositions (CP V-ARI and 90% CP V-ARI + 10% silica fume (SF)) when exposed to sodium sulfate and magnesium sulfate attack. Thermodynamic modeling was also used to determine the crystallization pressure of ettringite and gypsum. The XRD and TG results indicated that the incorporation of silica fume into the cement pastes reduced the precipitation of secondary ettringite under sodium sulfate exposure. However, this behavior was not observed under magnesium sulfate attack. The thermodynamic modeling showed good agreement with the experimental results. Regarding crystallization pressure, both pastes exhibited similar internal stresses. Finally, the results indicate that thermodynamic modeling is an effective tool for identifying and explaining the phases formed during sulfate attack in cementitious composites.

Translated title of the contribution	Thermodynamic modeling of Portland cement pastes exposed to sodium sulfate and magnesium sulfate
Original language	Portuguese (Brazil)
Article number	e149664
Journal	Ambiente Construído
Volume	26
Number of pages	21
ISSN	1678-8621
DOIs	https://doi.org/10.1590/s1678-86212026000100962
Publication status	Published - 2026

Keywords

Sulfate attack
Sodium sulfate
Magnesium sulfate
Thermodynamic modeling
Cement Portland

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@article{f690ca73a52349dd8a69189297913c40,

title = "Modelagem termodin{\^a}mica de pastas de cimento Portland expostas a sulfato de s{\'o}dio e sulfato de magn{\'e}sio",

abstract = "Sulfate attack in concrete structural elements can lead to the precipitation of expansive products, such as ettringite and gypsum, compromising the service life and durability of the material. This study aimed to investigate, through mineralogical (XRD) and thermal (TG/DTG) analyses combined with thermodynamic modeling, the behavior of two paste compositions (CP V-ARI and 90\% CP V-ARI + 10\% silica fume (SF)) when exposed to sodium sulfate and magnesium sulfate attack. Thermodynamic modeling was also used to determine the crystallization pressure of ettringite and gypsum. The XRD and TG results indicated that the incorporation of silica fume into the cement pastes reduced the precipitation of secondary ettringite under sodium sulfate exposure. However, this behavior was not observed under magnesium sulfate attack. The thermodynamic modeling showed good agreement with the experimental results. Regarding crystallization pressure, both pastes exhibited similar internal stresses. Finally, the results indicate that thermodynamic modeling is an effective tool for identifying and explaining the phases formed during sulfate attack in cementitious composites.",

keywords = "Sulfate attack, Sodium sulfate, Magnesium sulfate, Thermodynamic modeling, Cement Portland",

author = "\{Rossi Remenche\}, Igor and \{De Souza\}, \{Diego Jesus\} and \{Pereira Vizzotto\}, \{Andr{\'e} Luiz\} and \{Farias de Medeiros\}, \{Marcelo Henrique\} and \{Hoppe Filho\}, Juarez and Eduardo Pereira",

year = "2026",

doi = "10.1590/s1678-86212026000100962",

language = "Portugisisk (Brasilien)",

volume = "26",

journal = "Ambiente Constru{\'i}do",

issn = "1678-8621",

}

TY - JOUR

T1 - Modelagem termodinâmica de pastas de cimento Portland expostas a sulfato de sódio e sulfato de magnésio

AU - Rossi Remenche, Igor

AU - De Souza, Diego Jesus

AU - Pereira Vizzotto, André Luiz

AU - Farias de Medeiros, Marcelo Henrique

AU - Hoppe Filho, Juarez

AU - Pereira, Eduardo

PY - 2026

Y1 - 2026

N2 - Sulfate attack in concrete structural elements can lead to the precipitation of expansive products, such as ettringite and gypsum, compromising the service life and durability of the material. This study aimed to investigate, through mineralogical (XRD) and thermal (TG/DTG) analyses combined with thermodynamic modeling, the behavior of two paste compositions (CP V-ARI and 90% CP V-ARI + 10% silica fume (SF)) when exposed to sodium sulfate and magnesium sulfate attack. Thermodynamic modeling was also used to determine the crystallization pressure of ettringite and gypsum. The XRD and TG results indicated that the incorporation of silica fume into the cement pastes reduced the precipitation of secondary ettringite under sodium sulfate exposure. However, this behavior was not observed under magnesium sulfate attack. The thermodynamic modeling showed good agreement with the experimental results. Regarding crystallization pressure, both pastes exhibited similar internal stresses. Finally, the results indicate that thermodynamic modeling is an effective tool for identifying and explaining the phases formed during sulfate attack in cementitious composites.

AB - Sulfate attack in concrete structural elements can lead to the precipitation of expansive products, such as ettringite and gypsum, compromising the service life and durability of the material. This study aimed to investigate, through mineralogical (XRD) and thermal (TG/DTG) analyses combined with thermodynamic modeling, the behavior of two paste compositions (CP V-ARI and 90% CP V-ARI + 10% silica fume (SF)) when exposed to sodium sulfate and magnesium sulfate attack. Thermodynamic modeling was also used to determine the crystallization pressure of ettringite and gypsum. The XRD and TG results indicated that the incorporation of silica fume into the cement pastes reduced the precipitation of secondary ettringite under sodium sulfate exposure. However, this behavior was not observed under magnesium sulfate attack. The thermodynamic modeling showed good agreement with the experimental results. Regarding crystallization pressure, both pastes exhibited similar internal stresses. Finally, the results indicate that thermodynamic modeling is an effective tool for identifying and explaining the phases formed during sulfate attack in cementitious composites.

KW - Sulfate attack

KW - Sodium sulfate

KW - Magnesium sulfate

KW - Thermodynamic modeling

KW - Cement Portland

U2 - 10.1590/s1678-86212026000100962

DO - 10.1590/s1678-86212026000100962

M3 - Tidsskriftartikel

SN - 1678-8621

VL - 26

JO - Ambiente Construído

JF - Ambiente Construído

M1 - e149664

ER -

Modelagem termodinâmica de pastas de cimento Portland expostas a sulfato de sódio e sulfato de magnésio

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Keywords

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