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Mineral phases in metakaolin-portlandite pastes cured 15 years at 60 °C. New data for scientific advancement
Abstract One of the problems addressed by the scientific community in connection with cement matrix hydration is the evolution of hydrated phases under certain, primarily temperature-related, curing conditions. Such conditions are of utmost importance when the cement generates metastable hydrated phases that develop into stable phases, inducing substantial physical-mechanical changes in the matrix. One such instance arises during the pozzolanic reaction between metakaolinite and calcium hydroxide at 60 °C when metastable hexagonal phases co-exist with cubic stable phases. Such processes are well understood in the short and medium term (<5 years). Evolution at longer curing times has not been studied, however. This paper describes the evolution of the initial (stable and metastable) mineral phases in the metakaolinite / Ca(OH)2 reaction toward a zeolite-like phase after 15 year curing at 60 °C. An understanding of such mineralogical changes is scientifically significant, given their direct impact on the engineering properties of cement-based matrices.
Highlights Evolution mineralogical phases in MK-lime pastes during long time of curing. Formation of aggregates from the degradation of stable and metastable hydrated phases After 15 years of curing at 60 °C, gismondin-like zeolite is formed as a major phase.
Mineral phases in metakaolin-portlandite pastes cured 15 years at 60 °C. New data for scientific advancement
Abstract One of the problems addressed by the scientific community in connection with cement matrix hydration is the evolution of hydrated phases under certain, primarily temperature-related, curing conditions. Such conditions are of utmost importance when the cement generates metastable hydrated phases that develop into stable phases, inducing substantial physical-mechanical changes in the matrix. One such instance arises during the pozzolanic reaction between metakaolinite and calcium hydroxide at 60 °C when metastable hexagonal phases co-exist with cubic stable phases. Such processes are well understood in the short and medium term (<5 years). Evolution at longer curing times has not been studied, however. This paper describes the evolution of the initial (stable and metastable) mineral phases in the metakaolinite / Ca(OH)2 reaction toward a zeolite-like phase after 15 year curing at 60 °C. An understanding of such mineralogical changes is scientifically significant, given their direct impact on the engineering properties of cement-based matrices.
Highlights Evolution mineralogical phases in MK-lime pastes during long time of curing. Formation of aggregates from the degradation of stable and metastable hydrated phases After 15 years of curing at 60 °C, gismondin-like zeolite is formed as a major phase.
Mineral phases in metakaolin-portlandite pastes cured 15 years at 60 °C. New data for scientific advancement
Frías, M. (author) / Vigil de la Villa, R. (author) / Martínez-Ramírez, S. (author) / García-Giménez, R. (author) / Sánchez de Rojas, M.I. (author)
Applied Clay Science ; 184
2019-11-11
Article (Journal)
Electronic Resource
English
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