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Alkali–silica reactivity of large silica fume-derived particles
AbstractPozzolanic materials, including silica fume, are commonly added to concrete to reduce expansion due to alkali–silica reaction (ASR). It has been noted, however, that commercial silica fume is not always adequately dispersed, and large agglomerates may be present. These large particles have been hypothesized to act as amorphous silica aggregates, thereby participating in an expansive reaction with the alkalis present in cement paste pore solution. If such were the case, some silica fume particles would actually aggravate expansion due to ASR rather than suppress it. The present investigation characterizes the microstructure and morphology of agglomerated and sintered silica fume particles and compares their effects on alkali–silica-related expansion. While a 5% replacement of moderately reactive sand with sintered silica fume aggregates caused significant expansion under accelerated testing conditions (modified ASTM C1260), the replacement with large agglomerates of densified silica fume decreased expansion compared with control mortar bars containing only sand. Both the sintered aggregates and the agglomerates reacted with the pore solution; one reaction was expansive, while the other was not.
Alkali–silica reactivity of large silica fume-derived particles
AbstractPozzolanic materials, including silica fume, are commonly added to concrete to reduce expansion due to alkali–silica reaction (ASR). It has been noted, however, that commercial silica fume is not always adequately dispersed, and large agglomerates may be present. These large particles have been hypothesized to act as amorphous silica aggregates, thereby participating in an expansive reaction with the alkalis present in cement paste pore solution. If such were the case, some silica fume particles would actually aggravate expansion due to ASR rather than suppress it. The present investigation characterizes the microstructure and morphology of agglomerated and sintered silica fume particles and compares their effects on alkali–silica-related expansion. While a 5% replacement of moderately reactive sand with sintered silica fume aggregates caused significant expansion under accelerated testing conditions (modified ASTM C1260), the replacement with large agglomerates of densified silica fume decreased expansion compared with control mortar bars containing only sand. Both the sintered aggregates and the agglomerates reacted with the pore solution; one reaction was expansive, while the other was not.
Alkali–silica reactivity of large silica fume-derived particles
Juenger, M.C.G (author) / Ostertag, C.P (author)
Cement and Concrete Research ; 34 ; 1389-1402
2004-01-02
14 pages
Article (Journal)
Electronic Resource
English
Alkali-silica reactivity of large silica fume-derived particles
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Alkali-silica reactivity of large silica fume-derived particles
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Alkali-silica reactivity of large silica fume-derived particles
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