Acoustic emission study of heat-induced cracking in fly ash-based alkali-activated pastes and lightweight mortars

Alkali-activated fly ashes have been proposed for various applications where resistance against high temperatures is required, yet several details regarding the response of these materials to heat-exposure need to be clarified. In the present study, heat-induced cracking in fly ash-based alkali-activated pastes and lightweight mortars was analyzed by in-situ acoustic emission (AE)detection during complete heating-cooling cycles (up to ∼1100 °C), augmented by thermogravimetry and ex-situ SEM and XRD analyses. The applicability of the lightweight mortars as passive fire protection coatings was assessed by recording temperature-time curves of mortar-coated steel plates. Cracking during heating was limited and associated exclusively with the dehydration of the materials in the temperature range ∼90–360 °C. However, samples heated to temperatures above ∼600 °C exhibited intense cracking on cooling. This was attributed to differential deformations caused by local sintering and partial melting at the glass transition temperature, and subsequent quenching on cooling.



Titolo: Acoustic emission study of heat-induced cracking in fly ash-based alkali-activated pastes and lightweight mortars
Autore/i: Carabba L.; Pirskawetz S.; Kruger S.; Gluth G. J. G.; Bignozzi M. C.
Autore/i Unibo: 
CARABBA, LORENZA  
BIGNOZZI, MARIA  
mostra contributor esterni 
Anno: 2019
Rivista: 
CEMENT & CONCRETE COMPOSITES  
Digital Object Identifier (DOI): http://dx.doi.org/10.1016/j.cemconcomp.2019.04.013
Abstract: Alkali-activated fly ashes have been proposed for various applications where resistance against high temperatures is required, yet several details regarding the response of these materials to heat-exposure need to be clarified. In the present study, heat-induced cracking in fly ash-based alkali-activated pastes and lightweight mortars was analyzed by in-situ acoustic emission (AE)detection during complete heating-cooling cycles (up to ∼1100 °C), augmented by thermogravimetry and ex-situ SEM and XRD analyses. The applicability of the lightweight mortars as passive fire protection coatings was assessed by recording temperature-time curves of mortar-coated steel plates. Cracking during heating was limited and associated exclusively with the dehydration of the materials in the temperature range ∼90–360 °C. However, samples heated to temperatures above ∼600 °C exhibited intense cracking on cooling. This was attributed to differential deformations caused by local sintering and partial melting at the glass transition temperature, and subsequent quenching on cooling.
Data stato definitivo: 2020-02-22T01:12:34Z
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