The effect of end-plate wetting and unpinned contact lines on the filament thinning of strain hardening fluids

Neelakantan, Ravi; Unidad, Jerome; Karatay, Elif; Cocker, Eric; Ramesh, Palghat; Johnson, David M.

doi:10.1063/5.0018828

Cited by 4 publications

(2 citation statements)

References 41 publications

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“…Tensioned nanofibers with incomplete polymerization can be readily broken due to their low mechanical strength. In this study, we first draw suspended microfibers with sufficient UV exposure and leverage hydrodynamic force to further draw it by elasto-capillary thinning and reduce the diameter down to 47 nm. − …”

Section: Fabrication Of Lce Nanofibersmentioning

confidence: 99%

“…Lastly, we heated the fibers beyond 110 °C to stimulate the drag force (Figure f). The fiber continued to be further stretched, where the entangled molecular structure was extended to a better aligned status, and the diameter was greatly reduced due to the boost of flow-induced drag force − , (Figures h and S9). We found small beads within the suspended fiber, and a large volume of polymers accumulated at the end of fibers on the metal beams after this thermal treatment (Figure a). , The finest segment of LCE fibers could reach 47 nm at 130 °C.…”

Section: Fabrication Of Lce Nanofibersmentioning

confidence: 99%

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High Thermal Conductive Liquid Crystal Elastomer Nanofibers

Wang,

Wen,

Pan

et al. 2024

Nano Lett.

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Liquid crystal elastomers (LCEs), consisting of polymer networks and liquid crystal mesogens, show a reversible phase change under thermal stimuli. However, the kinetic performance is limited by the inherently low thermal conductivity of the polymers. Transforming amorphous bulk into a fiber enhances thermal conductivity through the alignment of polymer chains. Challenges are present due to their rigid networks, while cross-links are crucial for deformation. Here, we employ hydrodynamic alignment to orient the LCE domains assisted by controlled in situ cross-linking and to remarkably reduce the diameter to submicrons. We report that the intrinsic thermal conductivity of LCE fibers at room temperature reaches 1.44 ± 0.32 W/m-K with the sub-100 nm diameter close to the upper limit determined in the quasi-1D regime. Combining the outstanding thermal conductivity and thin diameters, we anticipate these fibers to exhibit a rapid response and high force output in thermomechanical systems. The fabrication method is expected to apply to other cross-linked polymers.

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Section: Fabrication Of Lce Nanofibersmentioning

confidence: 99%

Section: Fabrication Of Lce Nanofibersmentioning

confidence: 99%

High Thermal Conductive Liquid Crystal Elastomer Nanofibers

Wang,

Wen,

Pan

et al. 2024

Nano Lett.

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Formation of sub-100-nm suspended nanowires with various materials using thermally adjusted electrospun nanofibers as templates

Kwon

et al. 2023

Microsyst Nanoeng

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The air suspension and location specification properties of nanowires are crucial factors for optimizing nanowires in electronic devices and suppressing undesirable interactions with substrates. Although various strategies have been proposed to fabricate suspended nanowires, placing a nanowire in desired microstructures without material constraints or high-temperature processes remains a challenge. In this study, suspended nanowires were formed using a thermally aggregated electrospun polymer as a template. An elaborately designed microstructure enables an electrospun fiber template to be formed at the desired location during thermal treatment. Moreover, the desired thickness of the nanowires is easily controlled with the electrospun fiber templates, resulting in the parallel formation of suspended nanowires that are less than 100 nm thick. Furthermore, this approach facilitates the formation of suspended nanowires with various materials. This is accomplished by evaporating various materials onto the electrospun fiber template and by removing the template. Palladium, copper, tungsten oxide (WO3), and tin oxide nanowires are formed as examples to demonstrate the advantage of this approach in terms of nanowire material selection. Hydrogen (H2) and nitrogen dioxide (NO2) gas sensors comprising palladium and tungsten oxide, respectively, are demonstrated as exemplary devices of the proposed method.

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Correlation between the rheology of electronic inks and the droplet size generated from a capillary nozzle in dripping regime

Rijo,

Cremonezzi,

Andrade

et al. 2023

Physics of Fluids

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This study provides a complete rheological characterization of bidimensional (2D) nanomaterial dispersions, employed as 2D-inks precursors in printed electronics. Three different 2D nanomaterials [molybdenum disulfide (MoS2), graphene, and hexagonal boron nitride (hBN)] were dispersed in a Newtonian fluid (toluene) and a viscoelastic fluid (toluene + ethyl cellulose) with different polymer concentrations. The presence of nanosheets does not change the shear rheology of the carrier fluid. Regarding the extensional rheology, the results showed that the pinch-off phenomenon is present in all toluene suspensions; however, the presence of the ethyl cellulose introduces elasticity in the system, even leading to the formation of beads-on-a-string, and the relaxation times of the suspensions depend on the kind of nanosheets present in the fluid. As controlling the droplet size when dispensing 2D-inks is of paramount importance for printed electronics as well as for many other applications, here it is presented a correlation between the rheological properties of these 2D-inks precursors and their droplet size when generated from a capillary nozzle in the dripping regime.

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The effect of end-plate wetting and unpinned contact lines on the filament thinning of strain hardening fluids

Cited by 4 publications

References 41 publications

High Thermal Conductive Liquid Crystal Elastomer Nanofibers

High Thermal Conductive Liquid Crystal Elastomer Nanofibers

Formation of sub-100-nm suspended nanowires with various materials using thermally adjusted electrospun nanofibers as templates

Correlation between the rheology of electronic inks and the droplet size generated from a capillary nozzle in dripping regime

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