Nature of Steady-State Fast Flow in Entangled Polymer Melts: Chain Stretching, Shear Thinning, and Viscosity Scaling

Xu, Zipeng; Sun, Ruikun; Lu, Wei; Patil, Shalin; Mays, Jimmy W.; Schweizer, Kenneth S.; Cheng, Shiwang

doi:10.1021/acs.macromol.2c01345

Cited by 21 publications

(10 citation statements)

References 84 publications

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“…We would like to note that the SAOS measurement of polymers and filled polymers can be conducted to modulus of ∼10 9 Pa that is at least 1 order of magnitude higher than the shear modulus of semi-crystalline polymers in this study. 39 In our systems, all PP v samples had high fractions of the amorphous region (∼80 v %) that facilitate the SAOS measurements. To examine the influence of wallslip in the SAOS measurements for the PP v samples, we varied the testing gap from 0.80 to 0.95 mm and observed negligible changes in the shear modulus (Figure S1).…”

Section: Materials Characterizationmentioning

confidence: 83%

“…The strain amplitude was chosen to be 5% at 160 °C and gradually reduces to 0.05% for the temperature of 80 °C. We would like to note that the SAOS measurement of polymers and filled polymers can be conducted to modulus of ∼10 9 Pa that is at least 1 order of magnitude higher than the shear modulus of semi-crystalline polymers in this study . In our systems, all PP v samples had high fractions of the amorphous region (∼80 v %) that facilitate the SAOS measurements.…”

Section: Methodsmentioning

confidence: 93%

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Polymeric Dynamic Crosslinker for Upcycling of Fragile Low-Molecular-Weight Polypropylene

Sadri,

Patil,

Perkins

et al. 2023

ACS Appl. Polym. Mater.

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While tremendous progress has been made in the dynamic crosslinking of polypropylene (PP) for plastic upcycling, the efficacy in addressing low-molecular-weight (MW) PP waste remains untapped. In this work, we demonstrate a simple and scalable method to convert brittle low-MW PP to vitrimer materials with enhanced thermal and mechanical properties, enabling their use in circular upcycling. Different from most previous work employing small-molecule crosslinkers, we prepare PP vitrimers (PP v ) using polymeric crosslinkers, containing polyethylene glycol segments, which leads to altered crystalline structures and network formation. Importantly, by increasing the MW of crosslinkers from 200 to 1000 Da, the PP v exhibit more than 50 times increase in their fracture energy with strong ductility, which can be attributed to combined effects of strengthened amorphous regions of semicrystalline PP domains and the phase separation between soft polyethylene glycol segments and the PP matrix. Moreover, when blending the PP v with high MW PP (PP h ), the PP h /PP v blends show comparable elastic modulus, yield strength, and stretchability to that of the PP h , in sharp contrast to the widely known embrittlement of low-MW PP/PP h blends. These results demonstrate the use of polymeric dynamic crosslinkers as an important strategy for upcycling low-MW PP waste to value-added products.

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Section: Materials Characterizationmentioning

confidence: 83%

Section: Methodsmentioning

confidence: 93%

Polymeric Dynamic Crosslinker for Upcycling of Fragile Low-Molecular-Weight Polypropylene

Sadri,

Patil,

Perkins

et al. 2023

ACS Appl. Polym. Mater.

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“…We heated the extruder to 170 °C, slightly lower than the melting point, T m ≈ 200 °C, but much higher than the glass-transition temperature, T g ≈ 54 °C, of the glassy nodules in the dual-cross-linked network. To avoid typical die swell in polymer extrusion, in which the extrudate diameter is usually greater than the channel size, 39 we used a relatively low extrusion rate of 0.3 mm 3 /s to ensure that the extruded filament has a diameter comparable to the nozzle diameter. Synchronizing with the extrusion rate, we used a translation speed of the printhead at 100 mm/min.…”

Section: Diw Printingmentioning

confidence: 99%

3D Printable Modular Soft Elastomers from Physically Cross-linked Homogeneous Associative Polymers

Kim,

Nian,

Rau

et al. 2024

ACS Polym. Au

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printing of elastomers enables the fabrication of many technologically important structures and devices. However, there remains a critical need for the development of reprocessable, solvent-free, soft elastomers that can be printed without the need for post-treatment. Herein, we report modular soft elastomers suitable for direct ink writing (DIW) printing by physically cross-linking associative polymers with a high fraction of reversible bonds. We designed and synthesized linear-associative-linear (LAL) triblock copolymers; the middle block is an associative polymer carrying amide groups that form double hydrogen bonding, and the end blocks aggregate to hard glassy domains that effectively act as physical cross-links. The amide groups do not aggregate to nanoscale clusters and only slow down polymer dynamics without changing the shape of the linear viscoelastic spectra; this enables molecular control over energy dissipation by varying the fraction of the associative groups. Increasing the volume fraction of the end linear blocks increases the network stiffness by more than 100 times without significantly compromising the extensibility. We created elastomers with Young's moduli ranging from 8 kPa to 8 MPa while maintaining the tensile breaking strain around 150%. Using a high-temperature DIW printing platform, we transformed our elastomers to complex, highly deformable 3D structures without involving any solvent or post-print processing. Our elastomers represent the softest melt reprocessable materials for DIW printing. The developed LAL polymers synergize emerging homogeneous associative polymers with a high fraction of reversible bonds and classical block copolymer self-assembly to form a dual-cross-linked network, providing a versatile platform for the modular design and development of soft melt reprocessable elastomeric materials for practical applications.

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“…The onset of polymer shear thinning (reduction in the shear viscosity η) coincides with the onset of the alignment of the rod (reduction in the average angle ⟨θ⟩ with the shear direction). Investigating the nanoparticle–polymer coupling under out-of-equilibrium flow conditions will help design particle-based experiments to investigate nonlinear polymer rheology , as well as control the processing of nanoparticle–polymer composites under strong nonequilibrium flows such as encountered in 3D additive manufacturing.…”

Section: Recent Work On Nanoparticle–polymer Coupling In Various Scen...mentioning

confidence: 99%

Scaling Perspective on Dynamics of Nanoparticles in Polymers: Length- and Time-Scale Dependent Nanoparticle–Polymer Coupling

2023

Macromolecules

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The motion of nanoparticles in a polymer matrix is dictated by the intricate coupling of the nanoparticles and surrounding polymers. Various length- and time-scale dependent features of nanoparticle–polymer coupling in a polymer matrix have been delineated in the past decade by combining scaling theory and molecular simulations. Representative scenarios of nanoparticle dynamics in polymers, which embody the roles of polymer matrix topology, the polymers grafted to nanoparticle surface, the anisotropic shape of nanoparticles, and an external driving force, are reviewed. The systems examined demonstrate both the richness of the physics in the nanoparticle–polymer coupling and the capability of the scaling-level description in providing unique insights into the size- and time-dependence of nanoparticle mobility. Following a review of recent work, more scenarios of nanoparticles in polymer matrices, which reflect new pieces of physics in the nanoparticle–polymer coupling, are discussed. Together with the advances in the chemical synthesis of nanoparticles and polymers as well as in the techniques of tracking nanoparticle motion and measuring nanoparticle diffusivity, the microscopic picture of nanoparticle–polymer coupling revealed theoretically and computationally is anticipated to aid in the manipulation of nanoparticles in complex polymeric environments and thus benefit many technological applications.

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Nature of Steady-State Fast Flow in Entangled Polymer Melts: Chain Stretching, Shear Thinning, and Viscosity Scaling

Cited by 21 publications

References 84 publications

Polymeric Dynamic Crosslinker for Upcycling of Fragile Low-Molecular-Weight Polypropylene

Polymeric Dynamic Crosslinker for Upcycling of Fragile Low-Molecular-Weight Polypropylene

3D Printable Modular Soft Elastomers from Physically Cross-linked Homogeneous Associative Polymers

Scaling Perspective on Dynamics of Nanoparticles in Polymers: Length- and Time-Scale Dependent Nanoparticle–Polymer Coupling

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