High Reaction Activity of Nano-Size Phase of Silica Composite Binder

APA 6th edition
In-text: (Glagolev, Suleimanova & Lesovik, 2016)
Your Bibliography: Glagolev, E., Suleimanova, L. & Lesovik, V. (2016). High Reaction Activity of Nano-Size Phase of Silica Composite Binder. International Journal of Environmental and Science Education, 11(18), 12383-12389.

Harvard
In-text: (Glagolev, Suleimanova and Lesovik, 2016)
Your Bibliography: Glagolev, E., Suleimanova, L. and Lesovik, V. (2016). High Reaction Activity of Nano-Size Phase of Silica Composite Binder. International Journal of Environmental and Science Education, 11(18), pp. 12383-12389.

Chicago 16th edition
In-text: (Glagolev, Suleimanova and Lesovik 2016)
Your Bibliography: Glagolev, Evgenii, Liudmila Suleimanova and Valerii Lesovik (2016). "High Reaction Activity of Nano-Size Phase of Silica Composite Binder". International Journal of Environmental and Science Education 11 (18):12383-12389.

Abstract

The article covers the study of the influence of quartziferous additives on composition, structure of neo-crystallization and hydration of clinker minerals. It has been proven that adding chalk into composite binder composition creates conditions for the formation of a cement stone at the micro- and nanoscale and shows some activity (hydraulic or pozzolanic) increasing the total content of new formations in the hardening binder.

Keywords: cement stone, structure crystallization, screenings of crushing, composite binder, chalk, clinker minerals

References

Beandvin, J.J. (1976). Special reaction of portland cement. Cem. Res. Progr., 6, 45-64.

Chernyshov, E.M. & Korotkyh, D.N. (2008). Modifying the structure of cement stone of micro- and nanoscale particles of silica. Construction materials, equipment and technologies, 5, 30-32.

Dagotto, E., Hotto, Т. & Moreo, A. (2001). Colossal magnetoresistant materials, the key role of phase separation. Phys. Reports., 344, 148-153.

Guimond, R.J. (1989). Radioactivity released from phosphate containing fertilizers and from gypsum. Radiat. Phys. Chem., 34, 309-315.

Hobbs, D.W. (1981). The alcoli-silica reaction – a model for prediction expansion in Mortar. Mag. Сoncr. Res., 33, 208-219.

Kamaliev, R.T., Korneev, V.I. & Brykov, A.S. (2009). Portland cement with the addition of ultrafine silica. Cement and its Applications, 1, 86-89.

Kara, K.A. (2011). Aerated concrete on composite binders for monolithic construction. Belgorod: BSTU.

Klassen ,V., Shuravwlev, P. & Klassen, A. (2000). Synthese des niedrigbasischen Klinkers durch Verwendung der Schlackeabfälle und Herstellung des hochwertigen Mischzements. Inter. Baustofftagung, 1, 189-196.

Lesovik, R.V. & Zhernovsky, I.V. (2008). Selecting the silica-component composite binders. Construction materials, 8, 78-79.

Lesovik, V.S., Suleymanov, A.G. & Kara, K.A. (2010). Non-autoclaved aerated concrete on composite knitting for energy-efficient construction. Herald BSTU named after V.G. Shukhov, 4, 47-52.

Ming, T., Hengjing, V. & Ying, L. (2003). Investigation of the effect of silica fume and nano-SiOx on cement composites. J. Chin. Ceram. Soc., 31(5), 523-527.

Murtazaev, S.Y., Lesovik, V.S., Bataiev, K.S., Chernysheva, N.V. & Saidumov, M.S. (2015a). Fine-grainedcellular concrete creep analysis technique with consideration forcarbonation. Modern Applied Science, 9(4), 233-245.

Murtazaev, S.Y., Mintsaev, M.S., Saydumov, M.S. & Aliev, S.A. (2015b). Strength and strain properties of concrete, comprising filler, produced by screening of waste crushed concrete. Modern Applied Science, 9(4), 32-44.

Paschenko, A.A. (1991). The theory of cement. Kyiv: The builder.

Rietveld, H.M. (1969). A Profile Refinement Method for Nuclear and Magnetic Structures. J. Appl. Cryst., 2, 65-71.

Rietveld, Н.М. (1967). Line profiles of neutron powder-diffraction peaks for structure refinement. Acta Cryst., 22, 151-152.

Shmitko, E.I., Krylova, A.V. & Shatalova, V.V. (2006). Chemistry and cement binders. St.Peterburg: Science Avenue.

Suleymanova, L.A. & Kara, K.A. (2012a). Energy efficient aerated concrete on composite binders for monolithic building. News of higher educational institutions. Building, 3, 10-20.

Suleymanova, L.A. & Kara, K.A. (2012b). Optimization of non-autoclaved aerated concrete in the composite binder. Herald BSTU named after V.G. Shukhov, 2, 28-30.

Suleymanova, L.A., Lesovik, V.S. & Suleymanov, A.G. (2010). Non-autoclaved aerated concrete on composite knitting. Belgorod: BSTU.

Sulimenko, L.M. & Ukhanova, L.A. (2006). Ways to reduce energy costs for the production of lime-siliceous binders. Building materials, 6, 63-64.

Zhernovsky, I.V. (2010). Some features of the application of full-profile RFA in problems of building materials. Building materials. Nauka, 3, 2-5.

Zhernovsky, I.V., Shamshurov, A.V. (2012). The special composite binder for non-autoclave curing concretes. Herald BSTU named after V.G. Shukhov, 1, 39-45.

Zhernovsky, I.V., Strokova, V.V. & Fomenko, Y. (2007). On the influence of dimensional parameters of quartz polymorphs of its activity in the composite binding. Herald BSTU named after V.G. Shukhov, 4, 48-49.

Zhernovsky, I.V., Strokova. V.V. & Lesovik, V.S. (2008). To the problem of phase heterogeneity of quartz of sedimentary and metamorphic genesis. Mineralogia Polonica – Special Papers, 32, 175-177.