Particles size and distribution on the improvement of the mechanical performance of high strength solid solution based inorganic polymer composites: A microstructural approach

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Achile Nana
  • Elie Kamseu
  • Ange Therese Akono
  • Jean Ngouné
  • Jean Noel Yankwa Djobo
  • Hervé Kouamo Tchakouté
  • Maria Chiara Bognozzi
  • Cristina Leonelli

Externe Organisationen

  • University of Dschang
  • Ministry of Scientific Research and Innovation-Cameroon
  • University of Modena and Reggio Emilia
  • Northwestern University
  • University of Yaounde I
  • Università di Bologna
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer124602
FachzeitschriftMaterials chemistry and physics
Jahrgang267
Frühes Online-Datum13 Apr. 2021
PublikationsstatusVeröffentlicht - 15 Juli 2021
Extern publiziertJa

Abstract

This research reports on the influence of particle size and distribution on the physical, mechanical and microstructural features of solid solutions (feldspathic materials) based inorganic polymer composites (IPCs). Both granite and pegmatite were ground to different degree of finess making four different granulometry with particles of 63, 80, 125 and 200 μm. The respective mixes receive 15 wt% of metakaolin and were activated with a well designed alkaline solution. Matrices obtained showed high compressive and flexural strengths in the range 101.2–131.3 MPa, and 29–35.5 MPa, respectively. It was observed that the optimum mechanical performance of these matrices can be achieved through a mix-design of different grades of granulometry. This was suggested by mechanism combining reactivity and particles packing. In fact, although it can be expected that the finess of the combination of the particles size under 63 μm might present the better reactivity, it is showing that the combination of fine, medium and coarse particles is efficient in achieving denser and tougher microstructure. Lower cumulative pore volume (17 mL g−1) of the composites based on pegmatite, value not far from that of natural stones, resulted in a higher impact resistance of 3.03 J. It was concluded that designing the feldspathic rock-based composites with high strengths appear as sustainable, low energy consumption and environmentally-friendly materials for the structural construction.

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Particles size and distribution on the improvement of the mechanical performance of high strength solid solution based inorganic polymer composites: A microstructural approach. / Nana, Achile; Kamseu, Elie; Akono, Ange Therese et al.
in: Materials chemistry and physics, Jahrgang 267, 124602, 15.07.2021.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Nana A, Kamseu E, Akono AT, Ngouné J, Yankwa Djobo JN, Tchakouté HK et al. Particles size and distribution on the improvement of the mechanical performance of high strength solid solution based inorganic polymer composites: A microstructural approach. Materials chemistry and physics. 2021 Jul 15;267:124602. Epub 2021 Apr 13. doi: 10.1016/j.matchemphys.2021.124602
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T1 - Particles size and distribution on the improvement of the mechanical performance of high strength solid solution based inorganic polymer composites

T2 - A microstructural approach

AU - Nana, Achile

AU - Kamseu, Elie

AU - Akono, Ange Therese

AU - Ngouné, Jean

AU - Yankwa Djobo, Jean Noel

AU - Tchakouté, Hervé Kouamo

AU - Bognozzi, Maria Chiara

AU - Leonelli, Cristina

N1 - Publisher Copyright: © 2021 Elsevier B.V.

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N2 - This research reports on the influence of particle size and distribution on the physical, mechanical and microstructural features of solid solutions (feldspathic materials) based inorganic polymer composites (IPCs). Both granite and pegmatite were ground to different degree of finess making four different granulometry with particles of 63, 80, 125 and 200 μm. The respective mixes receive 15 wt% of metakaolin and were activated with a well designed alkaline solution. Matrices obtained showed high compressive and flexural strengths in the range 101.2–131.3 MPa, and 29–35.5 MPa, respectively. It was observed that the optimum mechanical performance of these matrices can be achieved through a mix-design of different grades of granulometry. This was suggested by mechanism combining reactivity and particles packing. In fact, although it can be expected that the finess of the combination of the particles size under 63 μm might present the better reactivity, it is showing that the combination of fine, medium and coarse particles is efficient in achieving denser and tougher microstructure. Lower cumulative pore volume (17 mL g−1) of the composites based on pegmatite, value not far from that of natural stones, resulted in a higher impact resistance of 3.03 J. It was concluded that designing the feldspathic rock-based composites with high strengths appear as sustainable, low energy consumption and environmentally-friendly materials for the structural construction.

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