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Abstract

Epoxy composites reinforced with pineapple leaf fiber (PALF) composites were fabricated and modified with three distinct flame retardants, namely aluminum hydroxide (Al(OH)₃), magnesium hydroxide (Mg(OH)₂), and 9,10-dihydro-9-oxa-10-phosphaphenanthrene-10-oxide (DOPO), at filler concentrations of 20, 40, and 60 wt.%. The samples were characterized using Limiting Oxygen Index (LOI), Shore D hardness, Raman spectroscopy, and thermo-mechanical analysis (TMA) as per the ASTM standards. The flame-retardant-modified composites exhibited significant improvement in LOI values compared to the neat composite (20% LOI), achieving 23–27% LOI with Al(OH)₃, 24–30% LOI with Mg(OH)₂, and 24–27% LOI with DOPO. The UL-94 vertical flammability testing showed that 40 wt.% of flame retardants achieved a V-0 rating, indicating superior self-extinguishing behavior. Scanning electron microscopy images of filler materials modified PALF composites displayed significant improvements. The use of Al(OH)₃ and Mg(OH)₂ filled the interfacial gaps and acted as barrier layers, helping to reduce the fiber exposure. DOPO-filled PALF composites observed with phosphorus-rich char precursors and porous protective structures. These features of flame-retardant filler materials improved char formation, suppressed the volatile release, and provided better condensed-phase protection. The Shore D hardness results observed with a moderate reduction in the hardness of modified composites compared to the neat composite. Raman spectral evaluation supported the char formation and water vapor release in Mg(OH)₂-modified composites, supporting its superior barrier action and alignment with LOI performance. TMA exhibited that the 40 wt.% Mg(OH)₂ observed to have a higher glass transition temperature (Tg) modified than that of the neat PALF composite. The reduction in coefficient of thermal expansion at the glassy and rubbery regions confirms that modified composites effectively restrict the polymer chain and provide better dimensional stability. Mg(OH)₂-modified PALF composites exhibit significantly better flame-retardant performance compared to neat PALF, which indicates their potential for use in fire-safe, lightweight materials.

Keywords

Pineapple leaf fiber (PALF)natural fiber reinforcement flame retardants fire-Safe sustainable materials and lightweight engineering

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References

Satyanarayana

Arizaga

GGC

Wypych

. Biodegradable composites based on lignocellulosic fibers—an overview. Prog Polym Sci 2009; 34: 982–1021.

Hiremath

Reddy

Mutra

, et al. Thermal degradation and fire retardant behaviour of natural fiber reinforced polymeric composites: a comprehensive review. J Mater Res Technol 2024; 30: 4053–4063.

Yadav

Verma

Kardam

, et al. Pineapple leaf fiber in polymer composites: structure, characterization, and applications. Mater Chem Phys Sustain Energy 2025; 2: 100011.

Lei

Zhao

, et al. Natural flame retardant minerals for advanced epoxy composites. Fire 2024; 7: 308.

Scionti

Piperopoulos

Atria

, et al. Effect of magnesium hydroxide and aluminum hydroxide as thermal barriers on the flame-retardant behavior of acrylic-based coating. Coatings 2023; 13: 1517.

Sriraman

Sreehari

Bharathi

, et al. Mechanical characteristics of glass epoxy composites with Yttrium powder fillers. Mater Today: Proc 2022; 50: 2462–2466.

Haque Protyai

Adib

Ibn Taher

, et al. Performance evaluation of Kevlar fiber reinforced epoxy composite by depositing graphene/SiC/Al₂O₃ nanoparticles. Hybrid Adv 2024; 6: 100245.

Mohit

Rangappa

Gapsari

, et al. Effect of bio-fibers and inorganic fillers reinforcement on mechanical and thermal characteristics on carbon–Kevlar–basalt–Innegra fiber bio/synthetic epoxy hybrid composites. J Mater Res Technol 2023; 23: 5440–5458.

Karthik

Udaya Prakash

Binoj

, et al. Effect of stacking sequence and silicon carbide nanoparticles on properties of carbon/glass/Kevlar fiber reinforced hybrid polymer composites. Polym Compos 2022; 43: 6096–6105.

10.

Sathiya Narayanan

Sai Venkat Mohan

Abhinay

, et al. Effects on microhardness, tensile strength, deflection, and drop weight impact resistance with the addition of hybrid filler materials for enhancing GFRP composites. Sci Rep 2024; 14: 27524.

11.

Beemkumar

Subbiah

Upadhye

, et al. Thermal stability and flame-retardant properties of a basalt/Kevlar fiber-reinforced hybrid polymer composite with bran filler particulates. Results Eng 2025; 25: 104207.

12.

Dun

Ouyang

Sun

, et al. A simple and efficient magnesium hydroxide modification strategy for flame-retardancy epoxy resin. Polymers (Basel) 2024; 16: 1471.

13.

Chen

, et al. Synthesis of highly dispersed magnesium hydroxide and its application in flame-retardant EVA composites. RSC Adv 2025; 15: 12854–12865.

14.

Kalali

Zhang

Shabestari

, et al. Flame-retardant wood polymer composites (WPCs) as potential fire safe bio-based materials for building products: preparation, flammability and mechanical properties. Fire Saf J 2019; 107: 210–216.

15.

Wang

. Impact of APP modified with DOPO group-containing silane coupling agent on flame retardancy and mechanical properties of epoxy resin. J Appl Polym Sci 2025; 142: e57554.

16.

Mohit

Sanjay

Siengchin

, et al. Predicting physico-mechanical and thermal properties of Loofa cylindrica fibers and Al₂O₃/Al-SiC reinforced polymer hybrid composites using artificial neural network techniques. Constr Build Mater 2023; 409: 133901.

17.

Prasad

Joseph

Sekar

. Investigation of mechanical, thermal and water absorption properties of flax fiber reinforced epoxy composite with nano TiO₂ addition. Compos Part A: Appl Sci Manuf 2018; 115: 360–370.

18.

Qian

Song

. Novel DOPO-based epoxy curing agents. J Therm Anal Calorim 2016; 126: 1339–1348.

19.

Wang

, et al. The flame retardant and mechanical properties of the epoxy modified by an efficient DOPO-based flame retardant. Polymers (Basel) 2024; 16: 631.

20.

Shen

, et al. Synergic effects of dimethyl methylphosphonate (DMMP) and nano-sized montmorillonite (MMT) on the flammability and mechanical properties of flax fiber reinforced phenolic composites under hydrothermal aging. Compos Sci Technol 2022; 230: 109487.

21.

Wang

. Effect of phosphorus-containing silane coupling agents modified ammonium polyphosphate on the flame retardancy and mechanical properties of epoxy resin. J Appl Polym Sci 2025; 142: e56807.

22.

Peng

Nie

, et al. A tetra-DOPO derivative as highly efficient flame retardant for epoxy resins. Polym Degrad Stab 2021; 193: 109715.

23.

Demirhan

Yurtseven

Usta

. The effect of boric acid on flame retardancy of intumescent flame retardant polypropylene composites including nanoclay. J Thermoplast Compos Mater 2021; 36: 1187–1214.

24.

Wang

. Synergistic flame retardancy of MIL-88B-Fe metal–organic framework with aluminum diethyl hypophosphite in epoxy resin. J Vinyl Addit Technol 2025; 31: 824–838.

25.

Agarwal

Ralph

Baez

, et al. Detection and quantitation of cellulose II by Raman spectroscopy. Cellulose 2021; 28: 9069–9079.

26.

Mortensen

Christensen

Nielsen

, et al. Raman spectra of amorphous Al₂O₃ and Al₂O₃/MoO₃ obtained by visible and infrared excitation. J Raman Spectrosc 1991; 22: 47–49.

27.

De Faria

DLA

Venâncio Silva

de Oliveira

. Raman Microspectroscopy of some iron oxides and oxyhydroxides. J Raman Spectrosc 1997; 28: 873–878.

28.

Dawson

Hadfield

Wilkinson

. The polarized infra-red and Raman spectra of Mg(OH)₂ and Ca(OH)₂. J Phys Chem Solids 1973; 34: 1217–1225.

29.

Gadzama

Sunmonu

Isiaku

, et al. Effects of surface modifications on the mechanical properties of reinforced pineapple leaf fiber polypropylene composites. Adv Chem Eng Sci 2020; 10: 24–39.

30.

Liao

Chen

Wang

. An update on pineapple leaf fibers. J Nat Fibres 2025; 22: 2509129.

31.

Wang

, et al. Synthesis of magnesium hydroxide flame retardant based on microcrystalline magnesite and its application in epoxy resin. Mater Res Express 2024; 11: 095009.

32.

Wang

, et al. The flame retardant and mechanical properties of the epoxy modified by an efficient DOPO-based flame retardant. Polymers (Basel) 2024; 16: 631.

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Effect of inorganic flame retardants on the thermo-mechanical and fire-resistant properties of pineapple leaf fiber composites

Abstract

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