Effects of Portland cement on activation mechanism of class F fly ash geopolymer cured under ambient conditions

A.M. Kaja; Alberto Lazaro Garcia; Q. Yu

doi:10.1016/j.conbuildmat.2018.09.065

Effects of Portland cement on activation mechanism of class F fly ash geopolymer cured under ambient conditions

A.M. Kaja, Alberto Lazaro Garcia, Q. Yu

Building Materials

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This study addresses the influence of a small Portland cement addition on the reaction kinetics and phase evolution of ambient cured class F fly ash-based geopolymer. The results show that setting time and reaction kinetics can be controlled by tailoring the precursor and activator characteristics, primarily the Ca/Si molar ratio. Calcium ions, dissolved from cement phases, contribute to a faster precipitation of products and in consequence, to a denser microstructure of composite pastes and a higher early age mechanical performance. However, excessive cement content impedes the gel formation due to hindered hydration of cement in high alkalinity at later ages and low compatibility between calcium deficient and calcium rich phases which lower the silica availability. It is found that the optimal dosage of cement in fly ash F based geopolymeric system is depending on the total silica content, 5 wt% and 7.5 wt% for silicate-based activator with a silica modulus of 1.2 and 1.5, respectively.

Originele taal-2	Engels
Pagina's (van-tot)	1113-1123
Aantal pagina's	11
Tijdschrift	Construction and Building Materials
Volume	189
DOI's	https://doi.org/10.1016/j.conbuildmat.2018.09.065
Status	Gepubliceerd - 20 nov. 2018

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The authors would like to acknowledge the financial support by NWO (The Netherlands Organisation for Scientific Research) for funding this research (project no. 12824). Furthermore, the authors wish to express their gratitude to the following sponsors of the Building Materials research group at TU Eindhoven: Rijkswaterstaat Grote Projecten en Onderhoud; Graniet-Import Benelux; Kijlstra Betonmortel; Struyk Verwo; Attero; Enci; Rijkswaterstaat Zee en Delta-District Noord; Van Gansewinkel Minerals; BTE; V.d. Bosch Beton; Selor; GMB; Icopal; BN International; Eltomation, Knuaf Gips; Hess AAC Systems; Kronos; Joma; CRH Europe Sustainable Concrete Centre; Cement & Beton Centrum; Heros; Inashco; Keim; Sirius International; Boskalis; NNERGY; Millvision; Sappi and Studio Roex (in chronological order of joining).

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10.1016/j.conbuildmat.2018.09.065

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title = "Effects of Portland cement on activation mechanism of class F fly ash geopolymer cured under ambient conditions",

abstract = "This study addresses the influence of a small Portland cement addition on the reaction kinetics and phase evolution of ambient cured class F fly ash-based geopolymer. The results show that setting time and reaction kinetics can be controlled by tailoring the precursor and activator characteristics, primarily the Ca/Si molar ratio. Calcium ions, dissolved from cement phases, contribute to a faster precipitation of products and in consequence, to a denser microstructure of composite pastes and a higher early age mechanical performance. However, excessive cement content impedes the gel formation due to hindered hydration of cement in high alkalinity at later ages and low compatibility between calcium deficient and calcium rich phases which lower the silica availability. It is found that the optimal dosage of cement in fly ash F based geopolymeric system is depending on the total silica content, 5 wt% and 7.5 wt% for silicate-based activator with a silica modulus of 1.2 and 1.5, respectively.",

keywords = "Ambient curing, Class F fly ash geopolymer, Compressive strength, Portland cement, Reaction kinetics, Setting time, Structural formation",

author = "A.M. Kaja and {Lazaro Garcia}, Alberto and Q. Yu",

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T1 - Effects of Portland cement on activation mechanism of class F fly ash geopolymer cured under ambient conditions

AU - Kaja, A.M.

AU - Lazaro Garcia, Alberto

AU - Yu, Q.

PY - 2018/11/20

Y1 - 2018/11/20

N2 - This study addresses the influence of a small Portland cement addition on the reaction kinetics and phase evolution of ambient cured class F fly ash-based geopolymer. The results show that setting time and reaction kinetics can be controlled by tailoring the precursor and activator characteristics, primarily the Ca/Si molar ratio. Calcium ions, dissolved from cement phases, contribute to a faster precipitation of products and in consequence, to a denser microstructure of composite pastes and a higher early age mechanical performance. However, excessive cement content impedes the gel formation due to hindered hydration of cement in high alkalinity at later ages and low compatibility between calcium deficient and calcium rich phases which lower the silica availability. It is found that the optimal dosage of cement in fly ash F based geopolymeric system is depending on the total silica content, 5 wt% and 7.5 wt% for silicate-based activator with a silica modulus of 1.2 and 1.5, respectively.

AB - This study addresses the influence of a small Portland cement addition on the reaction kinetics and phase evolution of ambient cured class F fly ash-based geopolymer. The results show that setting time and reaction kinetics can be controlled by tailoring the precursor and activator characteristics, primarily the Ca/Si molar ratio. Calcium ions, dissolved from cement phases, contribute to a faster precipitation of products and in consequence, to a denser microstructure of composite pastes and a higher early age mechanical performance. However, excessive cement content impedes the gel formation due to hindered hydration of cement in high alkalinity at later ages and low compatibility between calcium deficient and calcium rich phases which lower the silica availability. It is found that the optimal dosage of cement in fly ash F based geopolymeric system is depending on the total silica content, 5 wt% and 7.5 wt% for silicate-based activator with a silica modulus of 1.2 and 1.5, respectively.

KW - Ambient curing

KW - Class F fly ash geopolymer

KW - Compressive strength

KW - Portland cement

KW - Reaction kinetics

KW - Setting time

KW - Structural formation

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Effects of Portland cement on activation mechanism of class F fly ash geopolymer cured under ambient conditions

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