2012
DOI: 10.1134/s1070427212090042
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Effect of temperature treatment on the interaction of nanotubular magnesium silicate Mg3Si2O5(OH)4 with titanium tetrachloride and water vapors

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Cited by 4 publications
(1 citation statement)
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“…Practically, chrysotile is a bundle of interwoven nanotube fibers. The value of chrysotile as a reinforcing component in cement matrix is determined by its high mechanical strength of fibers (tensile strength up to 3000 MPa, modulus of elasticity is 1.6-2.1•10 4 MPa), sorption activity, adhesion to binders, and dispersive filling aggregates, as well as the possibility of forming strong topochemical bonds with them [19]. The distinctive feature of chrysotile asbestos compared to ordinary aggregates is its ability to retain chemically bound water almost without losses at prolonged exposure to high temperatures up to 450 • C. At higher temperatures, dehydration of chrysotile occurs, including the removal of hydrated water via the cavities of the nanotubes [18].…”
Section: Introductionmentioning
confidence: 99%
“…Practically, chrysotile is a bundle of interwoven nanotube fibers. The value of chrysotile as a reinforcing component in cement matrix is determined by its high mechanical strength of fibers (tensile strength up to 3000 MPa, modulus of elasticity is 1.6-2.1•10 4 MPa), sorption activity, adhesion to binders, and dispersive filling aggregates, as well as the possibility of forming strong topochemical bonds with them [19]. The distinctive feature of chrysotile asbestos compared to ordinary aggregates is its ability to retain chemically bound water almost without losses at prolonged exposure to high temperatures up to 450 • C. At higher temperatures, dehydration of chrysotile occurs, including the removal of hydrated water via the cavities of the nanotubes [18].…”
Section: Introductionmentioning
confidence: 99%