In recent years, there has been an increased focus on the research of earthen construction, driven by the rising demand for low-cost and sustainable building materials. Numerous studies have investigated the properties of compressed earth blocks (CEBs), however, very few have examined the properties of earth-based mortar. Mortar is an essential component and further investigation is required to enhance the mechanical performance of CEB structures. The study focuses on raw earth mortar (REM), which is a rudimentary mix of water with natural earth consisting of sand, silt and clay. Through experimental investigation, the fresh and hardened properties of three REM mixes were examined to determine the influence of cement stabilisation and jute fibre reinforcement. Shear triplet CEB assemblages were manufactured and tested to determine the initial shear strength of each mortar mix. The addition of 20 mm jute fibre at 0.25 % by weight increased the compressive and flexural strength of cement-stabilised raw earth mortar by 12 % and 20 % respectively. The addition of jute fibre also enhanced the initial shear strength, angle of internal friction and coefficient of friction during shear triplet testing. Finite element analysis (FEA) was undertaken to model the failure mechanism of the CEB assemblages, employing the use of cohesive zone modelling. The results of the FEA provided a satisfactory correspondence to the behaviour observed during experimental analysis and were within +/- 5.0 % of the expected values. The outcome of this investigation demonstrates the potential of REM and contributes to the development of low-cost and sustainable earth construction.

This work focused on the development of a hydrophobic biocomposite film reinforced with natural jute fiber. The biocomposite was made using a blend of chitosan and guar gum and reinforced with varying concentration of jute fiber followed by casting and air drying in petri dishes. Microscopic analysis of the cross-sectional structure of the films revealed a dense, compact morphology and FTIR result shows evidence of chemical interaction of the composite components. The inclusion of Jute fiber was found to increase the water repellant capacity of the films. The film water vapor permeability (WVP) was reduced from 4.1 x 10(-10) (g/m(2)center dot day center dot kPa) to 1.2 x 10(-10) (g/m(2)center dot day center dot kPa) with addition of jute fiber. Although the presence of Jute affects color properties of the films, it significantly improved their ability to block UV-Vis light. The tensile strength and elongation at break of CS/GG 0 % JT film, CS/GG/1 % JT, CS/GG/1.25 %JT and, CS/GG/1.5 % JT film was turned out to be (38.4 MPa, 45.3 MPa, 51.6 MPa and 60 MPa), (15.33 %, 17.66 %, 21.33 % and, 14 %) respectively. Notably, an increased in the DPPH radical scavenging assay was also observed from similar to 87 % in CS/GG composite to 99.4 % (1 % JT film), 99.66 % (1.25 %JT film) and 99.83 % for 1.5 % JT reinforced films respectively. Furthermore, all films showed excellent antimicrobial activity against the foodborne pathogen Escherichia coli and Fusarium oxysporum fungi highlighting their potential as active food packaging material. Signs of biodegradation were observed following four month of soil burial test, confirming the environmental sustainability of the produced biocomposite film.

The use of natural fibres has proven successful in improving the mechanical properties of earthen construction. It is a low-cost and environmentally friendly alternative to using chemical stabilisers, such as Portland Cement. This paper presents an experimental investigation into the influence of jute fibre reinforcement on the compressive and tensile splitting strength of Jute Reinforced Compressed Earth Composites (JRCECs). The investigation considered three fibre lengths (10 mm, 20 mm and 30 mm) and three fibre dosages (0.125%, 0.25% and 0.50%) by weight. When compared to an unreinforced control mix, it was found that the incorporation of jute fibre increased the mechanical properties of the JRCEC, with the optimum mix providing an increase in compressive and tensile splitting strength of 100% and 85% respectively. Within the investigation, Computed Tomography (CT) scans were performed on the JRCEC samples to evaluate the influence of mixing methodology on the fibre distribution and orientation. Findings from this study showed that jute fibre reinforcement may be used to increase the mechanical properties of compressed earth composites, and highlights the importance of mixing methodology during the manufacturing process.