TY - EJOU
AU - Tahar, Nur ‘Aisyah Ar-Raudhoh Mohammad
AU - Fadzli, Muhammad Haziq Mohd
AU - Mamauod, Siti Nur Liyana
AU - Zainal, Nahrul Hayawin
TI - Advancing Sustainable Materials: Nano-Palm Kernel Shell Biochar (n-PKSB) and Nano-Activated Biochar (n-APKS) as Renewable Fillers in Natural Rubber (NR) Biocomposites
T2 - Journal of Renewable Materials
PY -
VL -
IS -
SN - 2164-6341
AB - The palm oil industry is a major contributor to Malaysia’s economy, but its huge production has generated large amounts of oil palm biomass, particularly palm kernel shell (PKS), which poses environmental challenges if not properly managed. Converting PKS into biochar (PKSB) and activated carbon (APKS) offers a sustainable way to valorise this waste as potential bio-fillers in rubber composites. This study investigates the influence of nano-sized PKSB (n-PKSB) and activated PKS (n-APKS) as bio-fillers on the mechanical performance of natural rubber (NR) vulcanizates, with filler loadings ranging from 0 to 10 parts per hundred rubber (phr). The fillers were characterized using particle size analyzer (PSA), elemental analyzer, and Brunauer–Emmett–Teller (BET) analysis, while the filled NR vulcanizates were evaluated through swelling and abrasion tests. The PSA results showed average particle sizes of 10–11 nm for n-PKSB and 11–12 nm for n-APKS. The carbonization-activation process increased the carbon content (63%–65%) and BET surface area (520–540 m g−2) of n-APKS compared to n-PKSB (60%–62% and 47–50 m g−2, respectively). These enhancements promote stronger filler–rubber interfacial bonding and improved stress transfer within the matrix. Consequently, n-APKS-filled NR exhibited lower swelling index (219%) and volume loss (0.37 cm3) than n-PKSB filled NR vulcanizates (241% and 0.44 cm3), indicating better resistance to solvent penetration and abrasive forces. Both fillers achieved their optimal results at 5 phr loading. Thus, n-APKS and n-PKSB have potential as bio-fillers that will enhance rubber properties while reducing palm oil waste and contributing to long-term mitigation of environmental impact.
KW - Characterization; bio-filler reinforcement; mechanical properties; morphological analysis; rubber-filler interaction
DO - 10.32604/jrm.2025.02025-0177