Junior, Wiebke S.Wiebke S.JuniorEmmler, ThomasThomasEmmlerAbetz, ClarissaClarissaAbetzHandge, Ulrich A.Ulrich A.HandgeDos Santos, Jorge F.Jorge F.Dos SantosAmancio, SergioSergioAmancioAbetz, VolkerVolkerAbetz2021-05-142021-05-142014-08-19Polymer 55 (20): 5146-5159 (2014)http://hdl.handle.net/11420/9516In the present study, the feasibility of Friction Spot Welding (FSpW) of a commercial-grade poly(methyl methacrylate) (PMMA) (PMMA GS) and PMMA 6N/functionalized silica (SiO ) nanocomposites was investigated. The silica nanoparticles were functionalized via atom transfer radical polymerization (ATRP) with PMMA chains to achieve a uniform dispersion in the polymer matrix. The successful functionalization of silica nanoparticles with PMMA chains via ATRP was evaluated by ATR-FT-IR and TGA measurements. Rheological investigations of the silica nanocomposites showed a plateau of the storage modulus G′ at low frequencies (0.01-0.03 rad/s) as a result of elastic particle-particle interactions. Overlap friction spot welds consisting of PMMA GS and a 2 wt% SiO -g-PMMA nanocomposite were successfully prepared and compared to spot joints of PMMA GS welded with PMMA 6N and PMMA 6N/silica nanocomposite with 2 wt% unfunctionalized silica nanoparticles. Raman mappings of selected areas of cross-sectional plastographic specimens revealed an increased mixing behavior between the two polymer plates in the case of PMMA GS/2 wt% SiO -g-PMMA joints. Although the joints welded with PMMA 6N/silica nanocomposites showed a reduction of 22% in lap shear strength and 21% displacement at peak load compared with the neat PMMA spot welds, they can compete with other state-of-the-art PMMA welding techniques such as thermal bonding and ultrasonic welding, which indicates the potential of friction spot welding as an alternative fabrication technology for joining future nanocomposite engineering parts. 2 2 2en0032-386120142051465159Elsevier ScienceFriction spot weldingNanocompositesPMMAChemieJournal Article10.1016/j.polymer.2014.08.022Other