Effects of Molecular Weight of Functionalized Liquid Butadiene Rubber as a Processing Aid on the Properties of SSBR/Silica Compounds

• Published in: Polymers Vol. 13; no. 6; p. 850
• Main Authors: Kim, Donghyuk, Ahn, Byungkyu, Kim, Kihyun, Lee, JongYeop, Kim, Il Jin, Kim, Wonho
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 10.03.2021; MDPI
• Subjects: Abrasion resistance; Addition polymerization; Anionic polymerization; Butadiene; Chemical industry; Chromatography; Core loss; Energy dissipation; Functional groups; Glass transition temperature; liquid butadiene rubber; Manufacturing; Mechanical properties; Molecular weight; NMR; Nuclear magnetic resonance; Organic matter; Polymerization; Polymers; Rubber; rubber compounding; silica-filled compound; Silicon dioxide; Solvents; Spectrum analysis; SSBR; Sulfur; Tires; Viscoelasticity; Viscosity; Delaware; United States > US; Japan; Germany; silica-filled compound; liquid butadiene rubber; rubber compounding; SSBR; anionic polymerization
• ISSN: 2073-4360; 2073-4360
• DOI: 10.3390/polym13060850

Liquid butadiene rubber (LqBR) which used as a processing aid play a vital role in the manufacturing of high-performance tire tread compounds. However, the studies on the effect of molecular weight, microstructure, and functionalization of LqBR on the properties of compounds are still insufficient. In this study, non-functionalized and center-functionalized liquid butadiene rubbers (N-LqBR and C-LqBR modified with ethoxysilyl group, respectively) were synthesized with low vinyl content and different molecular weights using anionic polymerization. In addition, LqBR was added to the silica-filled SSBR compounds as an alternative to treated distillate aromatic extract (TDAE) oil, and the effect of molecular weight and functionalization on the properties of the silica-filled SSBR compound was examined. C-LqBR showed a low Payne effect and Mooney viscosity because of improved silica dispersion due to the ethoxysilyl functional group. Furthermore, C-LqBR showed an increased crosslink density, improved mechanical properties, and reduced organic matter extraction compared to the N-LqBR compound. LqBR reduced the glass transition temperature (T ) of the compound significantly, thereby improving snow traction and abrasion resistance compared to TDAE oil. Furthermore, the energy loss characteristics revealed that the hysteresis loss attributable to the free chain ends of LqBR was dominant.