[1]
H. Kurama, I. B. Topcu, C. Karakurt, Properties of the autoclaved aerated concrete produced from coal bottom ash, Journal of materials processing technology. 209.2 (2009) 767-773.
DOI: 10.1016/j.jmatprotec.2008.02.044
Google Scholar
[2]
R. Klingner. Autoclaved aerated concrete, Cambridge, UK, Woodhead, (2008).
Google Scholar
[3]
Jerman, Miloš, Hygric, thermal and durability properties of autoclaved aerated concrete, Construction and building materials. 41 (2013) 352-359.
DOI: 10.1016/j.conbuildmat.2012.12.036
Google Scholar
[4]
Hoff, C. George, Porosity-strength considerations for cellular concrete, Cement and Concrete Research. 2.1 (1972) 91-100.
DOI: 10.1016/0008-8846(72)90026-9
Google Scholar
[5]
N. Narayanan, K. Ramamurthy, Structure and properties of aerated concrete: a review, Cement and Concrete composites. 22.5 (2000) 321-329.
DOI: 10.1016/s0958-9465(00)00016-0
Google Scholar
[6]
H. Esmaily, H. Nuranian, Non-autoclaved high strength cellular concrete from alkali activated slag, Construction and Building Materials. 26.1 (2012) 200-206.
DOI: 10.1016/j.conbuildmat.2011.06.010
Google Scholar
[7]
S. Tada, S. Nakano, Microstructural approach to properties of moist cellular concrete, Proceedings Autoclaved Aerated Concrete, Moisture and Properties. Amsterdam: Elsevier (1983) 71-89.
Google Scholar
[8]
Wan-liang ZHOU, Jing-hua LONG, Bing-gen ZHAN, Further Study on Property of Fly Ash-Fluorogypsum-Cement Composite Binder, Journal of Building Materials. 2 (2008) 13-18.
Google Scholar
[9]
Fanghui Han, Characteristics of the hydration heat evolution of composite binder at different hydrating temperature, Thermochimica Acta. 586 (2014) 52-57.
DOI: 10.1016/j.tca.2014.04.010
Google Scholar
[10]
N.I. Alfimova, V.V. Kalatozi, S.V. Karatsupa, Ya.Yu. Vishnevskaya, M.S. Sheychenko, Mechanoactivation as a way to increase the efficiency of using raw materials of different genesis in construction materials, Vestnik Belgorod State Technological University V.G. Shukhov. 6 (2016) 85-89.
DOI: 10.12737/article_590878fa94e168.59204031
Google Scholar
[11]
Brandt, M. Andrzej Cement-based composites: materials, mechanical properties and performance, CRC Press, (2005).
Google Scholar
[12]
N.I. Alfimova, O.V. Koval'chenko, V.V. Kalatozi, Silicified concretes and composite astringents on technogenic raw materials, Comprehensive use of technogenic raw materials, Saarbrucken (2017).
Google Scholar
[13]
R. Lesovik, Y. Degtev, M. Shakarna, A. Levchenko, Green composites in architecture and building material science, Modern Applied Science Journal. 9.1 (2015) 45-50.
DOI: 10.5539/mas.v9n1p45
Google Scholar
[14]
A.A. Kuprina, V.S. Lesovik, L.H. Zagorodnyk, M.Y. Elistratkin, Anisotropy of materials properties of natural and man-triggered origin, Research Journal of Applied Sciences. 9.11 (2014) 816-819.
Google Scholar
[15]
N.I. Alfimova, E.E. Shadskiy, R.V. Lesovik, M.S. Ageeva, Organic-mineral modifier on the basis of volcanogenic-sedimentary rocks, International Journal of Applied Engineering Research. 10.24 (2015) 45131-45136.
Google Scholar
[16]
Y.M. Bazhenov, V.T. Erofeev, V.I. Rimshin, S.V. Markov, V.L. Kurbatov, Changes in the topology of a concrete porous space in interactions with the external medium, Engineering Solid Mechanics Journal. 4.4 (2016) 219-225.
DOI: 10.5267/j.esm.2016.5.001
Google Scholar
[17]
V.V. Nelyubova, V.V. Strokova, A.B. Buchalo, Non-autoclaved cellular composites with nanocomponents, Composition, structure, properties, Saarbrucken. (2017) 565-572.
Google Scholar
[18]
M.N. Sivalneva, N.V. Pavlenko, P.P. Pastushkov, V.V. Strokova, D.D. Netsvet, N.A. Shapovalov, Steam curing characteristics of cellular concrete on the base of nanostructured binder, Journal of Fundamental and Applied Sciences. 8.38 (2016) 1480-1488.
Google Scholar
[19]
N.I. Alfimova, V.S. Lesovik, E.S. Glagolev, Ya.Yu Vishnevskaya, Optimization of the curing conditions for composite astringents taking into account the genesis of the silica-containing component, Belgorod, (2016).
Google Scholar
[20]
M.S. Ageeva, N.I. Alfimova, Effective composite binder based on man-made raw materials, Saarbrucken. (2015).
Google Scholar
[21]
R.V. Lesovik, S.I. Leshchev, M.S. Ageeva, S.V. Karatsupa, N.I. Alfimova, The use of zeolite-containing rottenstone powder for the composite binding production, International Journal of Applied Engineering Research. 10.24 (2015) 44889.
Google Scholar