Litcius/Paper detail

Unlocking the potential of lignin: Towards a sustainable solution for tire rubber compound reinforcement

Sakrit Hait, Labeesh Kumar, Jyotirmaya Ijaradar, Anik Kumar Ghosh, Debapriya De, Jagannath Chanda, Prasenjit Ghosh, Saikat Das Gupta, Rabindra Mukhopadhyay, Sven Wießner, Gert Heinrich, Amit Das

2024Journal of Cleaner Production28 citationsDOIOpen Access PDF

Abstract

This study tackles the persistent challenge of producing highly reinforced lignin-rubber composites, emphasizing the transformation of agro-industrial residues into value-added products. To address this challenge, we introduce a novel approach termed “in-situ surface modification utilizing a thermo-chemo-mechanical approach” which incorporates the utilization of biomass-derived kraft lignin and a thermally stable organofunctional surface modifier, specifically (3-aminopropyl) triethoxysilane. The resulting material exhibits unprecedented tensile strength (∼15 MPa) along with ∼300 % elongation at break, while typical gum rubber offers 1–2 MPa tensile strength. Additionally, for the other tensile properties like 100 %, and 200 % tensile modulus, the improvement is 7-fold (∼5.6 MPa) and 10-fold (∼11.3 MPa), respectively. Furthermore, this composite presents a higher degree of reinforcement than a passenger car radial (PCR) tire model compound (tensile strength ∼14.5 MPa, 100 % tensile modulus ∼2.2 MPa, and 200 % tensile modulus ∼5.6 MPa) comprised of silica and polysulfide-based coupling agent, with exactly a similar loading of filler. The dynamic mechanical and stress relaxation behavior of the composites are critically discussed concerning the dispersion of the lignin in the sSBR/BR rubber matrix. The morphological orientation and involved chemical interaction in the presence of a surface modifier are also studied in detail. Tear fatigue analysis using pure shear specimens indicates superior fracture toughness at a lower tearing energy regime compared to silica-filled PCR tire compounds. Overall, this study showcases the potential of lignin-reinforced elastomers, offering a promising route for sustainable engineering materials and commercial viability.

Topics & Concepts

LigninReinforcementNatural rubberMaterials sciencePolymer scienceComposite materialBiochemical engineeringEngineeringChemistryOrganic chemistryLignin and Wood Chemistrybiodegradable polymer synthesis and propertiesAdvanced Cellulose Research Studies