Connor Colling scite author profile

Connor Colling

2Publications

9Citation Statements Received

75Citation Statements Given

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Membrane Technology & Research (United States), Shepherd University, University of Minnesota

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Porous Hydrophobic–Hydrophilic Composite Hollow Fiber and Flat Membranes Prepared by Plasma Polymerization for Direct Contact Membrane Distillation

et al. 2021

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High water vapor flux at low brine temperatures without surface fouling is needed in membrane distillation-based desalination. Brine crossflow over surface-modified hydrophobic hollow fiber membranes (HFMs) yielded fouling-free operation with supersaturated solutions of scaling salts and their precipitates. Surface modification involved an ultrathin porous polyfluorosiloxane or polysiloxane coating deposited on the outside of porous polypropylene (PP) HFMs by plasma polymerization. The outside of hydrophilic MicroPES HFMs of polyethersulfone was also coated by an ultrathin coating of porous plasma-polymerized polyfluorosiloxane or polysiloxane rendering the surface hydrophobic. Direct contact membrane distillation-based desalination performances of these HFMs were determined and compared with porous PP-based HFMs. Salt concentrations of 1, 10, and 20 wt% were used. Leak rates were determined at low pressures. Surface and cross-sections of two kinds of coated HFMs were investigated by scanning electron microscopy. The HFMs based on water-wetted MicroPES substrate offered a very thin gas gap in the hydrophobic surface coating yielding a high flux of 26.4–27.6 kg/m2-h with 1 wt% feed brine at 70 °C. The fluxes of HFMs on porous PP substrates having a long vapor diffusion path were significantly lower. Coated HFM performances have been compared with flat hydrophilic membranes of polyvinylidene fluoride having a similar plasma-polymerized hydrophobic polyfluorosiloxane coating.

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Environmental AFM as a Probe of the Morphology, Viscoelasticity and Lubricity of Crosslinked Hydrophilic Biomedical Coatings

et al. 2015

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We explore the morphology and tribo-mechanical properties of polyacrylate catheter coatings variably UV-crosslinked (1,4-butanediol diacrylate), as prepared and following variable tribological history under aqueous immersion (to mimick stresses during catheter deployment) to assess the lubricity and durability of coatings. A rich surface morphology is revealed over micro-to nanoscales, strongly dependent on both the extent of crosslinking and subsequent macrotribological processes. Submicron defect structures resulting from the sponge-coating deposition process include shallow (nm's) circular depressions hundreds of nanometers across ("cheetah spots") and much deeper/narrower "pinholes"; from the UV curing we find deep but larger in diameter "craters" plus "fissures" running between the deep holes and craters. The deepest defects exhibit modified behavior, as sensed in multiple AFM modes sensitive to dissipative properties (friction, adhesion, phase), consistent with these defects extending to the substrate, the Pebax catheter tube.Contact-mode "rippling", a form of wear due to shear forces during raster scanning by the tip, is a strong function of UV curing up to moderate curing times (10 seconds) but only weakly from moderate to long curing times (10-50 seconds). Examples of this phenomenological behavior are contrasted in Figure 1 for the cases of 5 and 10 second curing times. Slowly mapped AFM nanoindentation measurements are used to interrogate changes in both elastic and dissipative properties (i.e., viscoelasticity) of the coatings as a function of the above UV curing as well as subsequent aqueous macro-tribological history. Such nanomechanical responses are further explored under variable humidity and temperature (heated sample). A highly reproducible solvent-induced glass-rubber transition is identified over a narrow range of relative humidity (Figure 2), and found to be shifted to higher humidity on coatings that are "over cured" (50 seconds compared to 5-and 10-second curings). These 50 second UV coatings are also found to be nonlubricious in the macrotribological tests. In the process of exploring humidity cycles, dramatic irreversible transformations in coating morphology are fortuitously discovered, whereby many of the defects present from sponge coating and UV curing are largely "healed".Fast force-curve mapping mode is use for (i) zero-wear, high-resolution imaging (including imaging before/after ripple-inducing scanning as shown in Figure 1), wherein the smallest dissipative domains in tip-sample adhesion images become even smaller for higher UV curing times, thus suggesting sensitivity to the size of cooperatively rearranging regions in the glassy state; and (ii) quantifying glass-rubber transition, sensed in stiffness and adhesion images as a function of sample temperature. Broadly, this study demonstrates (1) technologically relevant and scientifically rich phenomenology over scales ranging from tens of microns to tens of nanometers; (2) connections of nanoscale dissipative behavior to macros...

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Connor Colling

Porous Hydrophobic–Hydrophilic Composite Hollow Fiber and Flat Membranes Prepared by Plasma Polymerization for Direct Contact Membrane Distillation

Environmental AFM as a Probe of the Morphology, Viscoelasticity and Lubricity of Crosslinked Hydrophilic Biomedical Coatings

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