Compressive Strengths and Microstructural Properties of Geopolymeric Materials Arising from the Addition of Semi-crystalline Alumina to Silica-rich Aluminosilicate Sources

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Hamed I. Riyap
  • B. K. Ngongang
  • Hervé Kouamo Tchakouté
  • C. P. Nanseu-Njiki
  • C. H. Rüscher

Research Organisations

External Research Organisations

  • University of Yaounde I
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Details

Original languageEnglish
Pages (from-to)10535-10558
Number of pages24
JournalSilicon
Volume14
Issue number16
Early online date11 Mar 2022
Publication statusPublished - Nov 2022

Abstract

This work aims to investigate the behaviour of the semi-crystalline alumina added to the aluminosilicates rich in amorphous and crystalline silica during the geopolymerization. Waste fired brick and metakaolin used in this work are rich in amorphous silica and quartz, respectively. Bauxite calcined at 600 °C was used as a semi-crystalline alumina source. The calcined product was added to each aluminosilicate with mass ratios calcined bauxite/metakaolin or calcined bauxite/waste fired brick equals 0, 0.1, 0.2, 0.3 and 0.4. Geopolymer pastes were obtained by adding sodium waterglass to each composition. The hardened pastes were cured at room temperature for 28 days before characterization. The compressive strengths of the geopolymer materials when the mass ratios of calcined bauxite/metakaolin are ranging from 0 to 0.3 increase from 36.33 to 55.09 MPa and drop from 55.09 to 43.19 MPa when that mass ratios increase from 0.3 to 0.4. Whereas those from waste fired brick decrease from 47.81 to 19.91 MPa with increasing the mass ratios. The spectra of the energy dispersive X-ray analysis of geopolymer materials from metakaolin and the one from waste fired brick without addition indicate the formation of Si-rich geopolymer networks. Whereas the one from waste fired brick after the addition of semi-crystalline alumina are mainly composed of Al-rich geopolymer structures. It can be concluded that the semi-crystalline alumina added to the metakaolin spread in the network of the final products while this alumina does not react with amorphous silica contained in the structure of waste fired brick during the geopolymerization.

Keywords

    Amorphous silica, Geopolymer materials, Metakaolin, Quartz, Semi-crystalline alumina, Waste fired brick

ASJC Scopus subject areas

Cite this

Compressive Strengths and Microstructural Properties of Geopolymeric Materials Arising from the Addition of Semi-crystalline Alumina to Silica-rich Aluminosilicate Sources. / Riyap, Hamed I.; Ngongang, B. K.; Tchakouté, Hervé Kouamo et al.
In: Silicon, Vol. 14, No. 16, 11.2022, p. 10535-10558.

Research output: Contribution to journalArticleResearchpeer review

Riyap HI, Ngongang BK, Tchakouté HK, Nanseu-Njiki CP, Rüscher CH. Compressive Strengths and Microstructural Properties of Geopolymeric Materials Arising from the Addition of Semi-crystalline Alumina to Silica-rich Aluminosilicate Sources. Silicon. 2022 Nov;14(16):10535-10558. Epub 2022 Mar 11. doi: 10.1007/s12633-022-01786-5
Riyap, Hamed I. ; Ngongang, B. K. ; Tchakouté, Hervé Kouamo et al. / Compressive Strengths and Microstructural Properties of Geopolymeric Materials Arising from the Addition of Semi-crystalline Alumina to Silica-rich Aluminosilicate Sources. In: Silicon. 2022 ; Vol. 14, No. 16. pp. 10535-10558.
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title = "Compressive Strengths and Microstructural Properties of Geopolymeric Materials Arising from the Addition of Semi-crystalline Alumina to Silica-rich Aluminosilicate Sources",
abstract = "This work aims to investigate the behaviour of the semi-crystalline alumina added to the aluminosilicates rich in amorphous and crystalline silica during the geopolymerization. Waste fired brick and metakaolin used in this work are rich in amorphous silica and quartz, respectively. Bauxite calcined at 600 °C was used as a semi-crystalline alumina source. The calcined product was added to each aluminosilicate with mass ratios calcined bauxite/metakaolin or calcined bauxite/waste fired brick equals 0, 0.1, 0.2, 0.3 and 0.4. Geopolymer pastes were obtained by adding sodium waterglass to each composition. The hardened pastes were cured at room temperature for 28 days before characterization. The compressive strengths of the geopolymer materials when the mass ratios of calcined bauxite/metakaolin are ranging from 0 to 0.3 increase from 36.33 to 55.09 MPa and drop from 55.09 to 43.19 MPa when that mass ratios increase from 0.3 to 0.4. Whereas those from waste fired brick decrease from 47.81 to 19.91 MPa with increasing the mass ratios. The spectra of the energy dispersive X-ray analysis of geopolymer materials from metakaolin and the one from waste fired brick without addition indicate the formation of Si-rich geopolymer networks. Whereas the one from waste fired brick after the addition of semi-crystalline alumina are mainly composed of Al-rich geopolymer structures. It can be concluded that the semi-crystalline alumina added to the metakaolin spread in the network of the final products while this alumina does not react with amorphous silica contained in the structure of waste fired brick during the geopolymerization.",
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TY - JOUR

T1 - Compressive Strengths and Microstructural Properties of Geopolymeric Materials Arising from the Addition of Semi-crystalline Alumina to Silica-rich Aluminosilicate Sources

AU - Riyap, Hamed I.

AU - Ngongang, B. K.

AU - Tchakouté, Hervé Kouamo

AU - Nanseu-Njiki, C. P.

AU - Rüscher, C. H.

N1 - Funding Information: Pr. Hervé Tchakouté Kouamo gratefully acknowledges Alexander von Humboldt-Stiftung for financial support for this work under the grant N° KAM/1155741 GFHERMES-P.

PY - 2022/11

Y1 - 2022/11

N2 - This work aims to investigate the behaviour of the semi-crystalline alumina added to the aluminosilicates rich in amorphous and crystalline silica during the geopolymerization. Waste fired brick and metakaolin used in this work are rich in amorphous silica and quartz, respectively. Bauxite calcined at 600 °C was used as a semi-crystalline alumina source. The calcined product was added to each aluminosilicate with mass ratios calcined bauxite/metakaolin or calcined bauxite/waste fired brick equals 0, 0.1, 0.2, 0.3 and 0.4. Geopolymer pastes were obtained by adding sodium waterglass to each composition. The hardened pastes were cured at room temperature for 28 days before characterization. The compressive strengths of the geopolymer materials when the mass ratios of calcined bauxite/metakaolin are ranging from 0 to 0.3 increase from 36.33 to 55.09 MPa and drop from 55.09 to 43.19 MPa when that mass ratios increase from 0.3 to 0.4. Whereas those from waste fired brick decrease from 47.81 to 19.91 MPa with increasing the mass ratios. The spectra of the energy dispersive X-ray analysis of geopolymer materials from metakaolin and the one from waste fired brick without addition indicate the formation of Si-rich geopolymer networks. Whereas the one from waste fired brick after the addition of semi-crystalline alumina are mainly composed of Al-rich geopolymer structures. It can be concluded that the semi-crystalline alumina added to the metakaolin spread in the network of the final products while this alumina does not react with amorphous silica contained in the structure of waste fired brick during the geopolymerization.

AB - This work aims to investigate the behaviour of the semi-crystalline alumina added to the aluminosilicates rich in amorphous and crystalline silica during the geopolymerization. Waste fired brick and metakaolin used in this work are rich in amorphous silica and quartz, respectively. Bauxite calcined at 600 °C was used as a semi-crystalline alumina source. The calcined product was added to each aluminosilicate with mass ratios calcined bauxite/metakaolin or calcined bauxite/waste fired brick equals 0, 0.1, 0.2, 0.3 and 0.4. Geopolymer pastes were obtained by adding sodium waterglass to each composition. The hardened pastes were cured at room temperature for 28 days before characterization. The compressive strengths of the geopolymer materials when the mass ratios of calcined bauxite/metakaolin are ranging from 0 to 0.3 increase from 36.33 to 55.09 MPa and drop from 55.09 to 43.19 MPa when that mass ratios increase from 0.3 to 0.4. Whereas those from waste fired brick decrease from 47.81 to 19.91 MPa with increasing the mass ratios. The spectra of the energy dispersive X-ray analysis of geopolymer materials from metakaolin and the one from waste fired brick without addition indicate the formation of Si-rich geopolymer networks. Whereas the one from waste fired brick after the addition of semi-crystalline alumina are mainly composed of Al-rich geopolymer structures. It can be concluded that the semi-crystalline alumina added to the metakaolin spread in the network of the final products while this alumina does not react with amorphous silica contained in the structure of waste fired brick during the geopolymerization.

KW - Amorphous silica

KW - Geopolymer materials

KW - Metakaolin

KW - Quartz

KW - Semi-crystalline alumina

KW - Waste fired brick

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DO - 10.1007/s12633-022-01786-5

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