Restricted accessResearch articleFirst published online 2026-1
Thermal and mechanical properties enhancement of plaster composites incorporating natural fibers and aggregates for application in sustainable buildings
Composite materials incorporating ecological additives, such as fibers and aggregates, have gained significant interest due to their sustainable and eco-friendly characteristics. This study investigates the thermo-mechanical characteristics of plaster composites reinforced with Moroccan sisal fibers and cork aggregates. The research examines the effects of different fiber lengths (1–4 cm), fiber percentages (1%–10%), and NaOH treatment concentrations (1%, 5%, and 10%) on the thermal conductivity, compressive strength, and flexural strength of the composites. Additionally, hybrid composites combining cork and sisal fibers are evaluated for their thermal and mechanical performance. The findings demonstrate that the used sisal fibers improve both thermal insulation and mechanical properties of the plaster composites, with optimal results achieved at the specific fiber content and length. While the inclusion of cork significantly enhances thermal insulation due to its low thermal conductivity. These results highlight the potential of sisal fibers and cork as sustainable reinforcement materials in construction, offering enhanced thermo-mechanical performance in building materials suitable plasterboard or paneling.
AhmadJMajdiAAhmedFD, et al. (2012) Concrete reinforced with sisal fibers (SSF): Overview of mechanical and physical properties. Crystals12: 952.
2.
AliSJainNSinghVK (2017) Review on mechanical properties of sisal fibre reinforced composites. In: Advance in engineering and technology for sustainable development, pp.1–3.
3.
AL-RidhaASDAbboodAAHusseinFM, et al. (2021) Effect of chopped sisal fiber (CSF) on enhancing the compressive strength of local plaster of Paris (LPOP). Materials Today Proceedings47: 2575–2579.
4.
AsdrubaliFSchiavoniSHoroshenkovKV (2012) A review of sustainable materials for acoustic applications. Building Acoustics19: 283–311.
5.
AtbirABoukhattemLKhabbaziA, et al. (2024) Manuscript title: Optimal mix study of sustainable lightweight composite bricks incorporating clay, wool and cork materials using circular economy approaches. Renewable and Sustainable Energy Reviews206: 114851.
6.
BazliMBazliL (2021) A review on the mechanical properties of fiber-reinforced polymer composites and their application in the Transportation Industry. Journal of Composites and Compounds3: 0–274.
7.
BerardiUIannaceG (2015) Acoustic characterization of natural fibers for sound absorption applications. Building and Environment94: 840–852.
8.
BouchefraIEl BichriFZChehouaniH, et al. (2022) Mechanical and thermophysical properties of compressed earth brick rienforced by raw and treated doum fibers. Construction and Building Materials318: 126031.
9.
BousshineSOuakarrouchMBybiA, et al. (2022) Acoustical and thermal characterization of sustainable materials derived from vegetable, agricultural, and animal fibers. Applied Acoustics187: 108520.
10.
BouzitSLaasriSTahaM, et al. (2019) Characterization of natural gypsum materials and their composites for building applications. Applied Sciences9: 2443.
11.
BouzitSMerliFSonebiM, et al. (2022) Investigation of thermal, mechanical and acoustic performance of bio-materials based on plaster-gypsum and cork. Construction Technologies and Architecture1: 685–690.
12.
CharaiMSghiouriHMezrhabA, et al. (2021) Thermal insulation potential of non-industrial hemp (Moroccan cannabis sativa L.) fibers for green plaster-based building materials. Journal of Cleaner Production292: 126064.
13.
CherkiAKhabbaziAIdchabaniR, et al. (2013) Experimental study of thermal insulation, energy storage capacity and lightness of cork-gypsum composite. Physical and Chemical News70: 59–66.
14.
CherkiABKhabbaziARemyB, et al. (2013) Granular cork content dependence of thermal diffusivity, thermal conductivity and heat capacity of the composite material/granular Cork bound with plaster. Energy Procedia42: 83–92.
15.
Di BellaGFioreVGaltieriG, et al. (2014) Effects of natural fibres reinforcement in lime plasters (kenaf and sisal vs. Polypropylene). Construction and Building Materials58: 159–165.
16.
ElfalehIAbbassiFHabibiM, et al. (2023) A comprehensive review of natural fibers and their composites: An eco-friendly alternative to conventional materials. Results in Engineering19: 101271.
17.
El WardiFZKhabbaziACherkiAB, et al. (2020) Thermomechanical study of a sandwich material with ecological additives. Construction and Building Materials252: 119093.
18.
Er-rradiHIdchabaniROubrekM, et al. (2022) Experimental study of composite materials based on ecological wastes. Journal of Composite Materials56: 3295–3306.
19.
FatmaNAllègueLSalemM, et al. (2019) The effect of doum palm fibers on the mechanical and thermal properties of gypsum mortar. Journal of Composite Materials53: 2641–2659.
20.
HarisNINHassanMZIlyasRA, et al. (2022) Dynamic mechanical properties of natural fiber reinforced hybrid polymer composites: A review. Journal of Materials Research and Technology19: 167–182.
21.
Hernández-OlivaresFBollatiMRdel RioM, et al. (1999) Development of cork–gypsum composites for building applications. Construction and Building Materials13: 179–186.
22.
JohnMThomasS (2008) Biofibres and biocomposites. Carbohydrate Polymers71: 343–364.
23.
KhabbaziAGaroumMTerhminaO (2005) Experimental study of thermal and mechanical properties of a new insulating material based on cork and cement mortar. Association for the Advancement of Modelling and Simulation Techniques in Enterprises74: 73–80.
24.
LabiadYMeddahABeddarM (2022) Physical and mechanical behavior of cement-stabilized compressed earth blocks reinforced by sisal fibers. Materials Today Proceedings53: 139–143.
25.
Laborel-PréneronAAubertJEMagniontC, et al. (2016) Plant aggregates and fibers in earth construction materials: A review. Construction and Building Materials111: 719–734.
26.
MatosAMNunesSSousa-CoutinhoJ (2015) Cork waste in cement based materials. Materials & Design85: 230–239.
27.
MillogoYMorelJCAubertJE, et al. (2014) Experimental analysis of pressed adobe blocks reinforced with Hibiscus cannabinus fibers. Construction and Building Materials52: 71–78.
28.
MokhtarR (2018) Physico-mechanical properties of plaster mortar reinforced with date palm fibers. Trends in Civil Engineering and its Architecture3: 1–5.
29.
Morales-CondeMJRodríguez-LiñánCPedreño-RojasMA (2016) Physical and mechanical properties of wood-gypsum composites from demolition material in rehabilitation works. Construction and Building Materials114: 6–14.
30.
MorlierPKhenferMM (1991) Effet de la longueur des fibres sur les propriétés mécaniques des ciments renforcés de fibres cellulosiques. Materials and Structures24: 185–190.
31.
MounirSMaaloufaYCherkiAB, et al. (2014) Thermal properties of the composite material clay/granular cork. Construction and Building Materials70: 183–190.
32.
NaiiriFLamisAMehdiS, et al. (2021) Performance of lightweight mortar reinforced with doum palm fiber. Journal of Composite Materials55: 1591–1607.
33.
NetoJQueirozHAguiarR, et al. (2022) A review of recent advances in hybrid natural fiber reinforced polymer composites. Journal Of Renewable Materials10: 561–589.
34.
NF EN 13279-1 (2008) Liants-plâtres et enduits à base de plâtre pour le bâtiment- Partie 1: Définitions et exigences.Novembre 2008.pdf.
35.
NF EN 13279-2 (2014) Liants-plâtres et enduits à base de plâtre pour le bâtiment- Partie 2: Méthodes d’éssai.Fevrier 2014.pdf.
36.
OuakarrouchMBousshineSBybiA, et al. (2022a) Acoustic and thermal performances assessment of sustainable insulation panels made from cardboard waste and natural fibers. Applied Acoustics199: 109007.
37.
OuakarrouchMEl AzharyKMansourM, et al. (2020) Thermal study of clay bricks reinforced by sisal-fibers used in construction in south of Morocco. Energy Reports6: 81–88.
38.
OuakarrouchMLaaroussiNGaroumM, et al. (2022b) Sustainable thermo-acoustical insulation material from cardboard waste and natural fibers: Elaboration and performance evaluation. Journal of Building Physics46: 372–392.
39.
OuhaibiSMrajjiOEl WaznaM, et al. (2022) Sisal-fibre based thermal insulation for use in buildings. Advances in Building Energy Research16: 489–513.
40.
Rashmi NayakJBochenJGołaszewskaM (2022) Experimental studies on the effect of natural and synthetic fibers on properties of fresh and hardened mortar. Construction and Building Materials347: 128550.
41.
RenGYaoBHuangH, et al. (2021) Influence of sisal fibers on the mechanical performance of ultra-high performance concretes. Construction and Building Materials286: 122958.
42.
SairSMandiliBTaqiM, et al. (2019) Development of a new eco-friendly composite material based on gypsum reinforced with a mixture of cork fibre and cardboard waste for building thermal insulation. Composites Communications16: 20–24.
43.
SamouhZCherkaouiOSoulatD, et al. (2021a) Identification of the physical and mechanical properties of Moroccan sisal yarns used as reinforcements for composite materials. Fibers9: 1–16.
44.
SamouhZMolnarKBoussuF, et al. (2019) Mechanical and thermal characterization of sisal fiber reinforced polylactic acid composites. Polymers for Advanced Technologies30: 529–537.
45.
SamouhZMolnárKHajbaS, et al. (2021b) Elaboration and characterization of biocomposite based on polylactic acid and Moroccan sisal fiber as reinforcement. Polymer Composites42: 3812–3826.
46.
SilvaSPSabinoMAFernandesEM, et al. (2005) Cork: Properties, capabilities and applications. International Materials Reviews50: 345–365.
47.
SivakandhanCMuraliGTamiloliN, et al. (2020) Studies on mechanical properties of sisal and jute fiber hybrid sandwich composite. Materials Today Proceedings21: 404–407.
48.
TouilMLachhebASaadaniR, et al. (2022) A new experimental strategy assessing the optimal thermo-mechanical properties of plaster composites containing Alfa fibers. Energy and Buildings262: 111984.
49.
VeerasimmanAShanmugamVRajendranS, et al. (2022) Thermal properties of natural fiber sisal based hybrid composites – A brief review. Journal of Natural Fibers19: 4696–4706.
50.
VishnuvardhanRKothariRRSivakumarS, et al. (2019) Experimental investigation on mechanical properties of sisal fiber reinforced epoxy composite. Materials Today Proceedings18: 4176–4181.
51.
XuGZhouGAlthoeyF, et al. (2023) Evaluation of properties of bio-composite with interpretable machine learning approaches: Optimization and hyper tuning. Journal of Materials Research and Technology25: 1421–1446.
