Modification of linear prepolymers to tailor heterogeneous network formation through photo-initiated polymerization-induced phase separation

Szczepanski, Caroline R.; Stansbury, Jeffrey W.

doi:10.1016/j.polymer.2015.06.002

Cited by 24 publications

(37 citation statements)

References 41 publications

(61 reference statements)

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“…In addition to comonomers, each formulation also included a varying amount (based on wt%) of a nonreactive, thermoplastic, fluoropolymer: poly(vinyl diene) fluoride (PVDF). Previous studies of phase‐separating polymerizations have often turned toward the use of a nonreactive additive to increase overall free energy of a polymerizing resin and thus promote the formation of heterogeneous structure through diffusion of incompatible phases . Here, PVDF is chosen as the nonreactive additive due to the favorable properties it imparts on the resulting coating.…”

Section: Resultsmentioning

confidence: 99%

“…Previous studies of phase-separating polymerizations have often turned toward the use of a nonreactive additive to increase overall free energy of a polymerizing resin and thus promote the formation of heterogeneous structure through diffusion of incompatible phases. [13,[25][26][27][28] Here, PVDF is chosen as the nonreactive additive due to the favorable properties it imparts on the resulting coating. This includes resistance to solvents, mechanical strength, and rigidity, as well as low surface energy.…”

Section: Resultsmentioning

confidence: 99%

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Rapid, Template‐Less Patterning of Polymeric Interfaces for Controlled Wettability via in Situ Heterogeneous Photopolymerizations

Szczepanski

Darmanin

Godeau

et al. 2018

Macro Chemistry & Physics

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Tuning macroscopic behavior between a synthetic surface and the surrounding environment requires precise engineering of micro‐ and nanoscale features at the interface. As one example, the geometry and spacing of topographical structures can be manipulated to modify interfacial interactions with water. If optimized correctly, topographical features can impart macroscopic wetting behavior that goes well beyond what is expected from the chemistry of the surface materials, such as strong hydrophobicity from intrinsically hydrophilic materials. However, developed techniques such as templating or nano‐lithography require significant processing times and are often ill‐suited for in situ applications. This work shows that polymeric interfaces with regular, ordered topographical features can be generated using a rapid in situ photopolymerization technique that requires no templating nor additional processing to generate or manipulate surface features. Maximizing the local differential in polymerization‐induced shrinkage between heterogeneous domains results in the formation of robust 3D surface features. Furthermore, the spacing and density of these features can be optimized through the phase separation process, yielding surfaces with variable wetting (θw ≈ 90–130°). These results demonstrate that template‐ and mask‐less surface patterning is possible with rapid polymerization techniques and that it can be easily manipulated to vary surface wetting behavior.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Rapid, Template‐Less Patterning of Polymeric Interfaces for Controlled Wettability via in Situ Heterogeneous Photopolymerizations

Szczepanski

Darmanin

Godeau

et al. 2018

Macro Chemistry & Physics

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“…Szczepanski et al [ 30 ] investigated the photo-polymerization of triethylene glycoldimethacrylate (TEGDMA) modified by poly(methyl methacrylate) (PMMA), which induced the phase separation and formed the heterogeneous network. The obtained tan delta profile showed the formation of two separated phases, one rich in TEGDMA, and the other rich in TEGDMA/PMMA.…”

Section: Introductionmentioning

confidence: 99%

Long-Range Surface-Directed Polymerization-Induced Phase Separation: A Computational Study

2021

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The presence of a surface preferably attracting one component of a polymer mixture by the long-range van der Waals surface potential while the mixture undergoes phase separation by spinodal decomposition is called long-range surface-directed spinodal decomposition (SDSD). The morphology achieved under SDSD is an enrichment layer(s) close to the wall surface and a droplet-type structure in the bulk. In the current study of the long-range surface-directed polymerization-induced phase separation, the surface-directed spinodal decomposition of a monomer–solvent mixture undergoing self-condensation polymerization was theoretically simulated. The nonlinear Cahn–Hilliard and Flory–Huggins free energy theories were applied to investigate the phase separation phenomenon. The long-range surface potential led to the formation of a wetting layer on the surface. The thickness of the wetting layer was found proportional to time t*1/5 and surface potential parameter h11/5. A larger diffusion coefficient led to the formation of smaller droplets in the bulk and a thinner depletion layer, while it did not affect the thickness of the enrichment layer close to the wall. A temperature gradient imposed in the same direction of long-range surface potential led to the formation of a stripe morphology near the wall, while imposing it in the opposite direction of surface potential led to the formation of large particles at the high-temperature side, the opposite side of the interacting wall.

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“…One of the most important concerns about incorporating nonreactive inorganic moiety into a photopolymerizing formulation is their tendency to undergo polymerization‐induced phase separation (PIPS). [1b,3] The Gibbs free energy of mixing thermodynamically determines the advancement of phase separation in a multicomponent mixture

Δ G^{mix} = Δ H^{mix} - T Δ S^{mix}

…”

Section: Introductionmentioning

confidence: 99%

“…Increasing the molecular weight of the nonreactive part not only promotes PIPS but also changes the mechanism of phase separation. Samples with a high molecular weight nonreactive part undergo phase separation through spinodal decomposition while samples with low molecular weight polymer additives undergo phase separation through nucleation and growth . Other studies have revealed that miscibility and crosslink density can affect the final morphology.…”

Section: Introductionmentioning

confidence: 99%

Manipulating the Surface Structure of Hybrid UV Curable Coatings through Photopolymerization‐Induced Phase Separation: Influence of Inorganic Portion and Photoinitiator Content

Nayini

Bastani

Moradian

et al. 2017

Macro Chemistry & Physics

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Surface topography and phase-manipulated distribution of hybrid UV curable coatings is performed. Accordingly, phase separation is controlled by changing the inorganic/organic ratio and the photoinitiator content as these are the main thermodynamic and kinetic affecting factors, respectively. Chemical and mechanical evolution of the samples during photopolymerization is investigated by time-resolved Fourier transform infrared spectroscopy and photorheometry, respectively. It is found that the samples that contain larger portion of inorganic oligomers are polymerized faster, but undergo gelation later; this provides them more time to undergo phase separation prior to gelation. Therefore, their surfaces become rougher and more heterogeneous, which is confirmed by atomic force microscopey. Furthermore, adding larger amounts of photoinitiator into the samples leads to them being photopolymerized faster and undergo gelation at lower conversion. So, they have less time and thermodynamic tendency to undergo phase separation prior to gelation; their surfaces thus become smoother and more homogeneous.

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Modification of linear prepolymers to tailor heterogeneous network formation through photo-initiated polymerization-induced phase separation

Cited by 24 publications

References 41 publications

Rapid, Template‐Less Patterning of Polymeric Interfaces for Controlled Wettability via in Situ Heterogeneous Photopolymerizations

Rapid, Template‐Less Patterning of Polymeric Interfaces for Controlled Wettability via in Situ Heterogeneous Photopolymerizations

Long-Range Surface-Directed Polymerization-Induced Phase Separation: A Computational Study

Manipulating the Surface Structure of Hybrid UV Curable Coatings through Photopolymerization‐Induced Phase Separation: Influence of Inorganic Portion and Photoinitiator Content

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