Tailoring nanorod alignment in a polymer matrix by elongational flow under confinement: simulation, experiments, and surface enhanced Raman scattering application

Park, Jay Hoon; Joo, Yong Lak

doi:10.1039/c4sm00096j

Cited by 25 publications

(20 citation statements)

References 40 publications

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“…It is worthy to note that our observations from DAA and FFT match computational predictions suggested by previous work, and further corroborate that application of controlled circumferentially uniform air flow in GAES results in better dispersion of nanoinclusions due to a strain enhanced agglomerate rupture and slightly from Taylor diffusion. This work provides a simple but powerful methodology to produce multifunctional nanocomposites with high surface area, where particle surface functionalization is not required.…”

Section: Resultssupporting

confidence: 91%

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Controlling the Placement of Spherical Nanoparticles in Electrically Driven Polymer Jets and its Application to Li‐Ion Battery Anodes

Zhmayev

Pinge

Shoorideh

et al. 2016

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Employing circumferentially uniform air flow through the sheath layer of the concentric coaxial nozzle, the gas-assisted electrospinning (GAES) utilizes both high electric field and controlled air flow to produce nanofibers. The ability to tailor the distribution of various nanofillers (1.85-12.92 vol% of spherical SiO and Si nanoparticles) in a polyvinyl alcohol jet is demonstrated by varying airflow rates in GAES. The distribution of nanofillers is measured from transmission electron microscopy and is analyzed using an image processing technique to perform the dispersion area analysis and obtain the most probable separation between nanoparticles using fast Fourier transform (FFT). The analysis in this study indicates an additional 350% improvement in dispersion area with the application of high but controlled airflow, and a 75 percent decrease in separation between nanoparticles from the FFT. The experiments in this study are in good agreement with a coarse-grained MD simulation prediction for a polymer nanocomposite system subjected to extensional deformation. Lastly, utilizing the sheath layer air flow in production of Li-battery anode material, a 680 mAh g improvement is observed in capacity for nanofibers spun via GAES compared to ES at the same Si NP loading, which is associated with better dispersion of the electrochemically active nanoparticles.

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Section: Resultssupporting

confidence: 91%

“…Lower separation values resemble improved spatial distribution and enhanced agglomerate rupture. The concept of the most probable separation is similar to the pair correlation function that is often used in CGMD studies on NP dispersion, and describes how density varies as a function of distance from any reference particle …”

Section: Introductionmentioning

confidence: 99%

Controlling the Placement of Spherical Nanoparticles in Electrically Driven Polymer Jets and its Application to Li‐Ion Battery Anodes

Zhmayev

Pinge

Shoorideh

et al. 2016

Small

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“…Therefore, for our coarse-grained model, each bead with its diameter equal to 1 nm corresponds to 5 repeating units of polyethylene, leading to the mass of each bead equal to 140g/mol. The nanorods gradually align along the shear direction under the shear force, 60,61 which is also consistent with our results even though the nanorods show the aggregation state because of attractive inter-nanorod interaction in their cases. 32, 58 However, for the nanorods with higher aspect ratio (16-mer in their system), the nanorods will self-assemble to form large bundles.…”

Section: Physical Chemistry Chemical Physics Accepted Manuscriptsupporting

confidence: 91%

Molecular dynamics simulation of the conductivity mechanism of nanorod filled polymer nanocomposites

Gao

Cao

et al. 2015

Phys. Chem. Chem. Phys.

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We adopted molecular dynamics simulation to study the conductive property of nanorod-filled polymer nanocomposites by focusing on the effects of the interfacial interaction, aspect ratio of the fillers, external shear field, filler-filler interaction and temperature. The variation of the percolation threshold is anti N-type with increasing interfacial interaction. It decreases with an increase in the aspect ratio. At an intermediate filler-filler interaction, a minimum percolation threshold appears. The percolation threshold decreases to a plateau with temperature. At low interfacial interaction, the effect of an external shear field on the homogeneous probability is negligible; however, the directional probability increases with shear rate. Moreover, the difference in conductivity probabilities is reduced for different interfacial interactions under shear. Under shear, the decrease or increase of conductivity probability depends on the initial dispersion state. However, the steady-state conductivity is independent of the initial state for different interfacial interactions. In particular, the evolution of the conductivity network structure under shear is investigated. In short, this study may provide rational tuning methods to obtain nanorod-filled polymer nanocomposites with high conductivity.

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“…[9][10][11] The extensional strain in this process both creates the nanoscale fibers and plays a role in the placement of nanoscale additives within the fibers. 12 For complex polymer systems such as block copolymers (BCP), which are known to self-assemble into mesoscale phases like cylinders and lamellae, shear and strain also affect the morphology and alignment of the material. 13 The microstructures produced by self-assembly make these composites useful as templates for producing interesting nanostructured materials.…”

Section: Introductionmentioning

confidence: 99%

Effect of elongational flow on immiscible polymer blend/nanoparticle composites: a molecular dynamics study

Shebert

Joo

2016

Soft Matter

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Using coarse-grained nonequilibrium molecular dynamics, the dynamics of a blend of the equal ratio of immiscible polymers mixed with nanoparticles (NP) are simulated. The simulations are conducted under planar elongational flow, which affects the dispersion of the NPs and the self-assembly morphology. The goal of this study is to investigate the effect of planar elongational flow on the nanocomposite blend system as well as to thoroughly compare the blend to an analogous symmetric block copolymer (BCP) system to understand the role of the polymer structure on the morphology and NP dispersion. Two types of spherical NPs are considered: (1) selective NPs that are attracted to one of the polymer components and (2) nonselective NPs that are neutral to both components. A comparison of the blend and BCP systems reveals that for selective NP, the blend system shows a much broader NP distribution in the selective phase than the BCP phase. This is due to a more uniform distribution of polymer chain ends throughout the selective phase in the blend system than the BCP system. For nonselective NP, the blend and BCP systems show similar results for low elongation rates, but the NP peak in the BCP system broadens as elongation rates approach the order-disorder transition. In addition, the presence of NP is found to affect the morphology transitions of both the blend and BCP systems, depending on the NP type.

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Tailoring nanorod alignment in a polymer matrix by elongational flow under confinement: simulation, experiments, and surface enhanced Raman scattering application

Cited by 25 publications

References 40 publications

Controlling the Placement of Spherical Nanoparticles in Electrically Driven Polymer Jets and its Application to Li‐Ion Battery Anodes

Controlling the Placement of Spherical Nanoparticles in Electrically Driven Polymer Jets and its Application to Li‐Ion Battery Anodes

Molecular dynamics simulation of the conductivity mechanism of nanorod filled polymer nanocomposites

Effect of elongational flow on immiscible polymer blend/nanoparticle composites: a molecular dynamics study

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