Crystal-Chemical and Thermal Properties of Decorative Cement Composites

Crystal-Chemical and Thermal Properties of Decorative Cement Composites

The advanced tendencies in building materials development are related to the design of cement composites with a reduced amount of Portland cement, contributing to reduced CO<sub>2</sub> emissions, sustainable development of used non-renewal raw materials, and decreased energy consumption...

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Main Authors: Vilma Petkova, Ventseslav Stoyanov, Bilyana Kostova, Vladislav Kostov-Kytin, Alexander Kalinkin, Irina Zvereva, Yana Tzvetanova
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Materials
Subjects:
white Portland cement
marble powder
cement replacement materials
thermal properties
reaction mechanism
Online Access:https://www.mdpi.com/1996-1944/14/17/4793
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spelling doaj-fe1f31fe54934a9eaf4db8bfb8e07b542021-09-09T13:50:35ZengMDPI AGMaterials1996-19442021-08-01144793479310.3390/ma14174793Crystal-Chemical and Thermal Properties of Decorative Cement CompositesVilma Petkova0Ventseslav Stoyanov1Bilyana Kostova2Vladislav Kostov-Kytin3Alexander Kalinkin4Irina Zvereva5Yana Tzvetanova6Institute of Mineralogy and Crystallography “Academician Ivan Kostov”, Bulgarian Academy of Sciences, Academic Georgi Bonchev Street, Building 107, 1113 Sofia, BulgariaFaculty of Construction, University of Structural Engineering and Architecture “Lyuben Karavelov”, 175 Suhodolska Street, 1373 Sofia, BulgariaDepartment of Natural Sciences, New Bulgarian University, 21 Montevideo Street, 1618 Sofia, BulgariaInstitute of Mineralogy and Crystallography “Academician Ivan Kostov”, Bulgarian Academy of Sciences, Academic Georgi Bonchev Street, Building 107, 1113 Sofia, BulgariaKola Science Centre, Tananaev Institute of Chemistry and Technology of Rare Elements and Mineral Raw Materials, Russian Academy of Sciences, 14 Fersman Street, 184209 Apatity, RussiaCenter for Thermal Analysis and Calorimetry, Staint-Petersburg State University Research Park, 26 Universitetskij Prospekt, 198504 Peterhof, RussiaInstitute of Mineralogy and Crystallography “Academician Ivan Kostov”, Bulgarian Academy of Sciences, Academic Georgi Bonchev Street, Building 107, 1113 Sofia, BulgariaThe advanced tendencies in building materials development are related to the design of cement composites with a reduced amount of Portland cement, contributing to reduced CO<sub>2</sub> emissions, sustainable development of used non-renewal raw materials, and decreased energy consumption. This work deals with water cured for 28 and 120 days cement composites: Sample A—reference (white Portland cement + sand + water); Sample B—white Portland cement + marble powder + water; and Sample C white Portland cement + marble powder + polycarboxylate-based water reducer + water. By powder X-ray diffraction and FTIR spectroscopy, the redistribution of CO<sub>3</sub><sup>2−</sup>, SO<sub>4</sub><sup>2−</sup>, SiO<sub>4</sub><sup>4−</sup>, AlO<sub>4</sub><sup>5−</sup>, and OH<sup>−</sup> (as O-H bond in structural OH<sup>−</sup> anions and O-H bond belonging to crystal bonded water molecules) from raw minerals to newly formed minerals have been studied, and the scheme of samples hydration has been defined. By thermal analysis, the ranges of the sample’s decomposition mechanisms were distinct: dehydration, dehydroxylation, decarbonation, and desulphuration. Using mass spectroscopic analysis of evolving gases during thermal analysis, the reaction mechanism of samples thermal decomposition has been determined. These results have both practical (architecture and construction) and fundamental (study of archaeological artifacts as ancient mortars) applications.https://www.mdpi.com/1996-1944/14/17/4793white Portland cementmarble powdercement replacement materialsthermal propertiesreaction mechanism
collection DOAJ
language English
format Article
sources DOAJ
author Vilma Petkova
Ventseslav Stoyanov
Bilyana Kostova
Vladislav Kostov-Kytin
Alexander Kalinkin
Irina Zvereva
Yana Tzvetanova
spellingShingle Vilma Petkova
Ventseslav Stoyanov
Bilyana Kostova
Vladislav Kostov-Kytin
Alexander Kalinkin
Irina Zvereva
Yana Tzvetanova
Crystal-Chemical and Thermal Properties of Decorative Cement Composites
Materials
white Portland cement
marble powder
cement replacement materials
thermal properties
reaction mechanism
author_facet Vilma Petkova
Ventseslav Stoyanov
Bilyana Kostova
Vladislav Kostov-Kytin
Alexander Kalinkin
Irina Zvereva
Yana Tzvetanova
author_sort Vilma Petkova
title Crystal-Chemical and Thermal Properties of Decorative Cement Composites
title_short Crystal-Chemical and Thermal Properties of Decorative Cement Composites
title_full Crystal-Chemical and Thermal Properties of Decorative Cement Composites
title_fullStr Crystal-Chemical and Thermal Properties of Decorative Cement Composites
title_full_unstemmed Crystal-Chemical and Thermal Properties of Decorative Cement Composites
title_sort crystal-chemical and thermal properties of decorative cement composites
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-08-01
description The advanced tendencies in building materials development are related to the design of cement composites with a reduced amount of Portland cement, contributing to reduced CO<sub>2</sub> emissions, sustainable development of used non-renewal raw materials, and decreased energy consumption. This work deals with water cured for 28 and 120 days cement composites: Sample A—reference (white Portland cement + sand + water); Sample B—white Portland cement + marble powder + water; and Sample C white Portland cement + marble powder + polycarboxylate-based water reducer + water. By powder X-ray diffraction and FTIR spectroscopy, the redistribution of CO<sub>3</sub><sup>2−</sup>, SO<sub>4</sub><sup>2−</sup>, SiO<sub>4</sub><sup>4−</sup>, AlO<sub>4</sub><sup>5−</sup>, and OH<sup>−</sup> (as O-H bond in structural OH<sup>−</sup> anions and O-H bond belonging to crystal bonded water molecules) from raw minerals to newly formed minerals have been studied, and the scheme of samples hydration has been defined. By thermal analysis, the ranges of the sample’s decomposition mechanisms were distinct: dehydration, dehydroxylation, decarbonation, and desulphuration. Using mass spectroscopic analysis of evolving gases during thermal analysis, the reaction mechanism of samples thermal decomposition has been determined. These results have both practical (architecture and construction) and fundamental (study of archaeological artifacts as ancient mortars) applications.
topic white Portland cement
marble powder
cement replacement materials
thermal properties
reaction mechanism
url https://www.mdpi.com/1996-1944/14/17/4793
work_keys_str_mv AT vilmapetkova crystalchemicalandthermalpropertiesofdecorativecementcomposites
AT ventseslavstoyanov crystalchemicalandthermalpropertiesofdecorativecementcomposites
AT bilyanakostova crystalchemicalandthermalpropertiesofdecorativecementcomposites
AT vladislavkostovkytin crystalchemicalandthermalpropertiesofdecorativecementcomposites
AT alexanderkalinkin crystalchemicalandthermalpropertiesofdecorativecementcomposites
AT irinazvereva crystalchemicalandthermalpropertiesofdecorativecementcomposites
AT yanatzvetanova crystalchemicalandthermalpropertiesofdecorativecementcomposites
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