Nanoparticle amount, and not size, determines chain alignment and nonlinear hardening in polymer nanocomposites

Varol, H. Samet; Meng, Fanyu; Hosseinkhani, B.; Malm, Christian; Bonn, Daniel; Bonn, Mischa; Zaccone, Alessio; Parekh, Sapun H.

doi:10.1073/pnas.1617069114

Cited by 26 publications

(20 citation statements)

References 45 publications

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“…Indeed, this is consistent with prior reports on the assembly behavior of sparse brush systems that revealed the formation of complex particle brush aggregate structures in film and composite systems. 15 , 16 , 30 …”

Section: Resultsmentioning

confidence: 99%

Thermomechanical Properties and Glass Dynamics of Polymer-Tethered Colloidal Particles and Films

et al. 2017

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Polymer-tethered colloidal particles (aka “particle brush materials”) have attracted interest as a platform for innovative material technologies and as a model system to elucidate glass formation in complex structured media. In this contribution, Brillouin light scattering is used to sequentially evaluate the role of brush architecture on the dynamical properties of brush particles in both the individual and assembled (film) state. In the former state, the analysis reveals that brush–brush interactions as well as global chain relaxation sensitively depend on grafting density; i.e., more polymer-like behavior is observed in sparse brush systems. This is interpreted to be a consequence of more extensive chain entanglement. In contrast, the local relaxation of films does not depend on grafting density. The results highlight that relaxation processes in particle brush-based materials span a wider range of time and length scales as compared to linear chain polymers. Differentiation between relaxation on local and global scale is necessary to reveal the influence of molecular structure and connectivity on the aging behavior of these complex systems.

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Section: Resultsmentioning

confidence: 99%

Thermomechanical Properties and Glass Dynamics of Polymer-Tethered Colloidal Particles and Films

et al. 2017

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“…Most of the drop occurs already for a very small strain, typically below 0.1. The strong dependence on the strain amplitude is due to the breakup of the filler network [1][2][3][4][5][6][7][8][9][10][11][12][13]. That is, in the undeformed state, if the filler particle (volume) fraction is larger than ≈0.3, they form a percolating network in the rubber matrix.…”

Section: Introductionmentioning

confidence: 99%

Linear and Nonlinear Viscoelastic Modulus of Rubber

Tolpekina¹,

Pyckhout‐Hintzen

Persson

2019

Lubricants

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“…Strikingly, at the top surfaces, the FGC with a total filler content of 20 vol% was more than twice stiffer (≈12.5 GPa vs ≈5.3 GPa) and harder (≈780 MPa vs ≈350 MPa) than the homogeneous LC containing exactly the same total filler content and was even stiffer (≈12.5 GPa vs ≈11 GPa) and harder (≈780 MPa vs ≈690 MPa) than the HC containing a twofold filler content of 40 vol%. Such a fact indicated an extreme reinforcement effect by the hybrid nanoparticles concentrated at the surface region of the FGC, where the closely packed particles might construct a strong particle–matrix interphase network, since the interparticle distance was as small as the particle size as observed from the TEM images (Figure j–k) . Crossing the coating sections, the LC and HC exhibited uniform mechanical properties, revealing homogeneous distributions of the nanoparticles throughout the coating thickness.…”

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confidence: 90%

“…Among the three coatings, the HC and FGC presented similar scratch depths under all loads tested and were both considerably more scratch‐resistant than the LC with less fraction of nanoparticles at the surface region. The depth difference between the various surfaces was more significant under higher loads, implying that the hybrid nanoparticles facilitated more stress transferring from the resin matrix to the stiff particles under higher stress or strain conditions . Using in situ SPM imaging, the surface morphology of the residual scratch dents was visualized and displayed representatively in Figure b for the various surfaces and loads tested.…”

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confidence: 99%

Bioinspired Wear‐Resistant and Ultradurable Functional Gradient Coatings

Wang

Huang

et al. 2018

Small

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For mechanically protective coatings, the coating material usually requires sufficient stiffness and strength to resist external forces and meanwhile matched mechanical properties with the underneath substrate to maintain the structural integrity. These requirements generate a conflict that limits the coatings from achieving simultaneous surface properties (e.g., high wear‐resistance) and coating/substrate interfacial durability. Herein this conflict is circumvented by developing a new manufacturing technique for functional gradient coatings (FGCs) with the material composition and mechanical properties gradually varying crossing the coating thickness. The FGC is realized by controlling the spatial distribution of magnetic‐responsive nanoreinforcements inside a polymer matrix through a magnetic actuation process. By concentrating the reinforcements with hybrid sizes at the surface region and continuously diminishing toward the coating/substrate interface, the FGC is demonstrated to exhibit simultaneously high surface hardness, stiffness, and wear‐resistance, as well as superb interfacial durability that outperforms the homogeneous counterparts over an order of magnitude. The concept of FGC represents a mechanically optimized strategy in achieving maximal performances with minimal use and site‐specific distribution of the reinforcements, in accordance with the design principles of many load‐bearing biological materials. The presented manufacturing technique for gradient nanocomposites can be extended to develop various bioinspired heterogeneous materials with desired mechanical performances.

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Nanoparticle amount, and not size, determines chain alignment and nonlinear hardening in polymer nanocomposites

Cited by 26 publications

References 45 publications

Thermomechanical Properties and Glass Dynamics of Polymer-Tethered Colloidal Particles and Films

Thermomechanical Properties and Glass Dynamics of Polymer-Tethered Colloidal Particles and Films

Linear and Nonlinear Viscoelastic Modulus of Rubber

Bioinspired Wear‐Resistant and Ultradurable Functional Gradient Coatings

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