Evidence of the Transition from a Flexible to Rigid Percolating Network in Polymer Nanocomposites

Nguyen, Hung K.; Nakajima, Ken

doi:10.1021/acs.macromol.2c00208

Cited by 13 publications

(13 citation statements)

References 64 publications

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“…As the filler fraction increases beyond 10 wt %, however, we observe significant differences in mechanical reinforcement among the different morphologies. 58 In the limits of high or low graft densities (samples A−F), we observe minimal reinforcement, even at the highest NP loading. These samples show a behavior similar to that predicted by the Guth−Gold model.…”

Section: Mechanical Propertiesmentioning

confidence: 77%

Mechanical Properties of Polyisoprene-Based Elastomer Composites

Dhara,

Rahman,

Ruzicka

et al. 2024

Macromolecules

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We have explored the origins of mechanical reinforcement in elastomers filled with polymer-grafted nanoparticles (NPs). The brush chains are constructed from the same monomers as the polymer melt, although they have different microstructures (i.e., different amounts of trans and cis isomers). The NPs display a variety of morphologies depending on variations in the graft density of the polymers, with these morphologies hardly changing when the matrix (and the grafts) is cross-linked using dicumyl peroxide (DCP). NMR measurements show that the cross-link densities depend only on the DCP content and are independent of NP morphologies. We find that the elastic moduli of these materials are strongly dependent on the NP morphology but that the maximum reinforcement occurs when the NPs percolate, in a manner where the cores are exposed enough to have strong enthalpic interactions; these interactions could either be due to direct core−core van der Waals attractions or due to bridging interactions driven by polymers adsorbed on adjacent NPs. The nonlinear mechanical response of these materials is less sensitive to changes in NP morphology and loading. These results emphasize the important role of the exposed NP surface in determining the moduli of cross-linked elastomers. This last aspect is apparently less relevant for the corresponding uncross-linked melts filled with NPs.

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Section: Mechanical Propertiesmentioning

confidence: 77%

Mechanical Properties of Polyisoprene-Based Elastomer Composites

Dhara,

Rahman,

Ruzicka

et al. 2024

Macromolecules

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“…It is well known that nanoparticles can affect the whole viscoelastic spectrum over a wide range of time (or frequency) scales; 22−27 however, the reinforcement was mostly discussed under specific states of polymers, namely, the glassy state, 26,28 the rubbery state, 26,27,29 and the viscous flow state. 16,22,24,25 In the rubbery zone of polymers, reinforcement mechanisms are complicated due to the interaction between nanoparticles and polymers.…”

Section: ■ Introductionmentioning

confidence: 99%

“…23,24,37 Overlap of the glassy layer at high filler concentration results in bridging chains percolated glassy domains, significantly increasing the rubbery plateau modulus. 27,32,38 The conformation of the adsorbed chains also plays an important role. The loop conformation may induce additional entanglements with matrix chains and increases the rubbery plateau modulus due to higher entanglement density near particles.…”

Section: ■ Introductionmentioning

confidence: 99%

“…It is well known that nanoparticles can affect the whole viscoelastic spectrum over a wide range of time (or frequency) scales; − however, the reinforcement was mostly discussed under specific states of polymers, namely, the glassy state, , the rubbery state, ,, and the viscous flow state. ,,, In the rubbery zone of polymers, reinforcement mechanisms are complicated due to the interaction between nanoparticles and polymers. ,,,,− The spatial confinement and the attractive interaction lead to a bound polymer layer, , where segmental dynamics are greatly suppressed. , The constrained polymer around particles with a shift of the glass transition temperature ( T g ) in the vicinity of particles could increase the effective radius of particles and contributes to the enhancement of the plateau modulus in PNCs via the increment of effective filler volume fraction. ,, Overlap of the glassy layer at high filler concentration results in bridging chains percolated glassy domains, significantly increasing the rubbery plateau modulus. ,, The conformation of the adsorbed chains also plays an important role. The loop conformation may induce additional entanglements with matrix chains and increases the rubbery plateau modulus due to higher entanglement density near particles. , The effect of interfacial chain conformation was found to rely on the effective specific surface area of particles, , which can be readily evaluated for well-dispersed nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

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Quantitative Correlation between Hierarchical Nanofiller Structure and Rheology of Polymer/Fumed Silica Nanocomposites

et al. 2023

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Understanding the mechanical reinforcement of polymer nanocomposites (PNCs) filled with agglomerated nanofillers has attracted considerable attention in the past century, but a quantitative description of linear rheology over a wide range of time scales is still a challenge at present. In this study, the hierarchical nanofiller structure and its relationship to the rheology of fumed silica-filled poly(methyl methacrylate) nanocomposites are quantitatively investigated using transmission electron microscopy, smallangle X-ray scattering, and rheological measurements. It is suggested that the polymer entanglements dominate the short-time rheological behavior of nanocomposites, and the enhancement in the rubbery modulus is controlled by the interfacial adsorption-induced entanglements, which depend on the effective surface fractal dimension of nanofillers. At a longer time scale, the discrete agglomerates and the particle networks dominate the modulus enhancement. It was found that there is a power−law relationship between the particle network modulus and the inter-agglomerate mesh size with an exponent of −5, corresponding to a chemical dimension of 1 and rigid particle chains. A new two-phase model is suggested for the linear rheology of PNCs, including the contribution of interfacial entanglements, discrete agglomerates, and particle networks. The linear viscoelasticity of PNCs can be quantitatively described using properly determined structural parameters of particle agglomerates.

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“…The mechanical properties of polymer hydrogels can be further tailored by incorporating nanomaterials to form polymer nanocomposite hydrogels. , Mechanical reinforcement emerges from the adsorption of polymer chains to nanomaterial surfaces. − Nanomaterial–polymer interactions increase the density of effective cross-links throughout the polymer nanocomposite hydrogel, thereby increasing the bulk elastic modulus. − Interestingly, nanocomposite stiffness is independent of nanomaterial size and governed by the volume fraction ϕ nano according to the Guth–Gold model: G ∞ ′ G 0 , ∞ ′ = 1 + 2.5 ϕ nano + 14.1 ϕ nano 2 where G ∞ ′ and G 0,∞ ′ are the elastic moduli of polymer networks with and without added nanomaterials, respectively.…”

Section: Introductionmentioning

confidence: 99%

Gelation Dynamics during Photo-Cross-Linking of Polymer Nanocomposite Hydrogels

et al. 2022

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Embedding nanomaterials into polymer hydrogels enables the design of functional materials with tailored chemical, mechanical, and optical properties. Nanocapsules that protect interior cargo and disperse readily through a polymeric matrix have drawn particular interest for their ability to integrate chemically incompatible systems and to further expand the parameter space for polymer nanocomposite hydrogels. The properties of polymer nanocomposite hydrogels depend on the material composition and processing route, which were explored systematically in this work. The gelation kinetics of network-forming polymer solutions with and without silica-coated nanocapsules bearing polyethylene glycol (PEG) surface ligands were investigated using in situ dynamic rheology measurements. Network-forming polymers comprised either 4-arm or 8arm star PEG with terminal anthracene groups, which dimerize upon irradiation with ultraviolet (UV) light. The PEG-anthracene solutions exhibited rapid gel formation upon UV exposure (365 nm); gel formation was observed as a crossover from liquid-like to solid-like behavior during in situ small-amplitude oscillatory shear rheology. This crossover time was non-monotonic with polymer concentration. Far below the overlap concentration (c/c* ≪ 1), spatially separated PEG-anthracene molecules were subject to forming intramolecular loops over intermolecular cross-links, thereby slowing the gelation process. Near the polymer overlap concentration (c/c* ∼ 1), rapid gelation was attributed to the ideal proximity of anthracene end groups from neighboring polymer molecules. Above the overlap concentration (c/c* > 1), increased solution viscosities hindered molecular diffusion, thereby reducing the frequency of dimerization reactions. Adding nanocapsules to PEG-anthracene solutions resulted in faster gelation than nanocapsule-free PEG-anthracene solutions with equivalent effective polymer concentrations. The final elastic modulus of nanocomposite hydrogels increased with nanocapsule volume fraction, signifying synergistic mechanical reinforcement by nanocapsules despite not being cross-linked into the polymer network. Overall, these findings quantify the impact of nanocapsule addition on the gelation kinetics and mechanical properties of polymer nanocomposite hydrogels, which are promising materials for applications in optoelectronics, biotechnology, and additive manufacturing.

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Evidence of the Transition from a Flexible to Rigid Percolating Network in Polymer Nanocomposites

Cited by 13 publications

References 64 publications

Mechanical Properties of Polyisoprene-Based Elastomer Composites

Mechanical Properties of Polyisoprene-Based Elastomer Composites

Quantitative Correlation between Hierarchical Nanofiller Structure and Rheology of Polymer/Fumed Silica Nanocomposites

Gelation Dynamics during Photo-Cross-Linking of Polymer Nanocomposite Hydrogels

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