Thermomechanical and physicochemical investigation of Raw clay bricks derived from Nomayo clay and palm shell powder lignocellulosic material

Thermomechanical and physicochemical investigation of Raw clay bricks derived from Nomayo clay and palm shell powder lignocellulosic material

Abstract This study proposes an in-depth characterization of the physicochemical, thermal and mechanical properties of unfired clay bricks derived from Nomayos clay (Cameroon), with progressive additions of palm kernel shell powder bio-based material (0 to 60% by mass). The aim was to assess the inf...

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Bibliographic Details
Main Authors: Hamka Hamka Adolphe Claudel, Olembe Roland Yves, Djomi Rolland, Ngohe Ekam Paul Salomon, Touani Chualeu Parfait, Biyeme Florent, Tchotang Theodore
Format: Article
Language:English
Published: Nature Portfolio 2025-08-01
Series:Scientific Reports
Subjects:
Unfired clay bricks clay
Palm kernel shell powder
Thermophysical properties
Mechanical strength
Sustainable building materials
Bio-based material
Online Access:https://doi.org/10.1038/s41598-025-13839-x
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Summary:Abstract This study proposes an in-depth characterization of the physicochemical, thermal and mechanical properties of unfired clay bricks derived from Nomayos clay (Cameroon), with progressive additions of palm kernel shell powder bio-based material (0 to 60% by mass). The aim was to assess the influence of lignocellulosic palm kernel shell powder on the physical and mechanical properties of unfired clay bricks, with a view to proposing a sustainable, lightweight, low-cost construction solution. To this end, physical analysis revealed a significant reduction in density (22–35%) with increasing organic matter content, attributed to the lower density of palm kernel shells. Scanning electron microscopy coupled with energy dispersive X-ray spectroscopy (SEM-EDX) confirms a homogeneous distribution of the main elements (C, O, Mg, Fe, Si, Al, Na, K, Ti). X-ray diffraction and Fourier transform infrared spectroscopy analysis show kaolinite as the main mineral phase, with a little amount of quartz and organic functional groups in composite samples. Thermal analysis (TGA/DTA/DTG) indicates a three-stage decomposition process: moisture loss (~ 188 °C), cellulose degradation (~ 314 °C, Δm ≈ 19.17%), and kaolinite dehydroxylation (> 500 °C), with thermal stability reached above 600 °C. Mechanical tests show a progressive decrease in compressive strength from 4.64 MPa (A0%) to 0.12 MPa (A60%), inversely correlated with organic filler content. Despite the decline in mechanical performance, these bricks show potential for lightweight, ecological and low-cost construction.
ISSN:2045-2322

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