Light-Directed Organization of Polymer Materials from Photoreactive Formulations

Hosein, Ian D.

doi:10.1021/acs.chemmater.9b05373

Cited by 10 publications

(15 citation statements)

References 65 publications

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“…Directing the organization of polymer blends into new structures and morphologies is an important approach toward the creation of soft materials with functional properties. 1 Specifically, producing polymer materials from reactive blends enables the concurrent assembly of complex structures over the course of polymerization. The reaction-induced increase in molecular weight can render the blend thermodynamically immiscible, thereby driving polymerization-induced phase separation (PIPS).…”

Section: Introductionmentioning

confidence: 99%

“…Most recently, photoreactive polymer blends have been organized using single arrays of optical beams transmitted through photoreactive monomer blend media that are sensitized to undergo photoinitiation at the optical beam’s particular wavelength. 1 , 11 The optical beams are observed to undergo a self-focusing nonlinearity, associated with a photochemically induced increase in refractive index, which counters the optical beam’s natural divergence. 12 − 17 The dynamic balance of self-focusing and divergence leads to self-trapped beams, which propagate divergence-free, or beams with reduced divergence transmitted through the polymer blend medium.…”

Section: Introductionmentioning

confidence: 99%

“…As a result, the polymer blend morphology evolves via spatially controlled phase separation uniformly along its depth, with one polymer component in the regions of the optical beams (i.e., regions of irradiation) and the other in the nonirradiated regions surrounding it, effectively organizing the blend into the same pattern as the ensemble of transmitted optical beams. 1,11,15 The structure and morphology of the blend can then be controlled via light intensity, 15 optical beam size and interspacing in an array, 18 formulation composition and component molecular weight, 19−21 and component volume fractions. 19 To advance the complexity of the organized structures, there is interest in examining structure formation in polymer blend media irradiated with multiple, nonparallel arrays of optical beams.…”

Section: ■ Introductionmentioning

confidence: 99%

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Simulations of Structure and Morphology in Photoreactive Polymer Blends under Multibeam Irradiation

Ding

Hosein

2022

J. Phys. Chem. C

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We present a theoretical study of the organization of photoreactive polymer blends under irradiation by multiple arrays of intersecting optical beams. In a simulated medium possessing an integrated intensity-dependent refractive index, optical beams undergo self-focusing and reduced divergence. A corresponding intensity-dependent increase in molecular weight induces polymer blend instability and consequent phase separation, whereby the medium can evolve into an intersecting waveguide lattice structure, comprising high refractive index cylindrical cores and a surrounding low refractive index medium (cladding). We conduct simulations for two propagation angles and a range of thermodynamic, kinetic, and polymer blend parameters to establish correlations to structure and morphology. We show that spatially correlated structures, namely, those that have a similar intersecting three-dimensional (3D) pattern as the arrays of intersecting optical beams, are achieved via a balance between the competitive processes of photopolymerization rate and phase separation dynamics. A greater intersection angle of the optical beams leads to higher correlations between structures and the optical beam pattern and a wider parameter space that achieves correlated structures. This work demonstrates the potential to employ complex propagating light patterns to create 3D organized structures in multicomponent photoreactive soft systems.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

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Simulations of Structure and Morphology in Photoreactive Polymer Blends under Multibeam Irradiation

Ding

Hosein

2022

J. Phys. Chem. C

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“…This is in good agreement with measurements of degrees of phase separation in previous work. 29 , 40 As the collection ranges were not significantly different between the two CQ concentrations, the collection angles could not be used to back-calculate any difference in the degrees of phase separation of the blends when using different CQ amounts. It is possible that differences observed in subsequent solar cell performance (to be discussed in the next section) are a result more so of internal waveguide morphology.…”

Section: Resultsmentioning

confidence: 99%

Multidirectional Polymer Waveguide Lattices for Enhanced Ultrawide-Angle Light Capture in Silicon Solar Cells

Ding

Hosein

2022

ACS Appl. Energy Mater.

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We report the synthesis and characterization of a polymer thin-film structure consisting of two intersecting broadband optical waveguide lattices, and its performance in wide-angle optical energy collection and conversion in silicon solar cells. The structures are synthetically organized via the concurrent irradiation of photoreactive polymer blends by two arrays of intersecting, microscale optical beams transmitted through the medium. Through optical beam-induced photopolymerization and photopolymerization-induced phase separation, well-organized lattices are produced comprising of cylindrical core–cladding waveguide architectures that intersect one another. The optical waveguide properties of the lattices transform the transmission characteristics of the polymer film so that incident optical energy is collected and transmitted along the waveguide axes, rather than their natural directions dictated by refraction, thereby creating efficient light-collecting capability. The embedded structures collectively impart their wide-angle acceptance ranges to enable the film to efficiently collect and interact with light over a large angular range (±70°). When employed as the encapsulant material for a commercial silicon solar cell, the novel light collection and transmission properties result in greater wide-angle conversion efficiency and electrical current density, compared to a single vertically aligned waveguide array. The sustained and greater conversion of light afforded by the encapsulating optical material promises to increase solar cell performance by enabling ultrawide-angle solar energy conversion.

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“…1,2,10 To address the challenges outlined above, here we report an approach based on photopolymerization-induced phase separation (referred to herein as PhIPS) in photopolymer− NP formulations to develop surface-patterned polymer composite superhydrophobic materials. PhIPS is a unique method for the directed organization of materials, 24 which we leverage herein to uniquely organize structured materials simultaneously from two different components, that is, the polymer and the NPs without the use of solvents, in thin casted films. By inducing PhIPS in a casted thin film of the formulation, the photopolymer evolves into a substrate with periodically spaced "bumps" in the regions of elevated curing rate, and the phase separation of the NPs is directed to the top surface of the polymer substrate, thereby producing a dense, yet thin, NP overlayer.…”

Section: Introductionmentioning

confidence: 99%

Superhydrophobic Polymer Composite Surfaces Developed via Photopolymerization

Pathreeker

Chando

Chen

et al. 2021

ACS Appl. Polym. Mater.

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Fabrication of superhydrophobic materials using incumbent techniques involves several processing steps and is therefore either quite complex, not scalable, or often both. Here, the development of superhydrophobic surface-patterned polymer–TiO 2 composite materials using a simple, single-step photopolymerization-based approach is reported. The synergistic combination of concurrent, periodic bump-like pattern formation created using irradiation through a photomask and photopolymerization-induced nanoparticle (NP) phase separation enables the development of surface textures with dual-scale roughness (micrometer-sized bumps and NPs) that demonstrate high water contact angles, low roll-off angles, and desirable postprocessability such as flexibility, peel-and-stick capability, and self-cleaning capability. The effect of nanoparticle concentration on surface porosity and consequently nonwetting properties is discussed. Large-area fabrication over an area of 20 cm 2 , which is important for practical applications, is also demonstrated. This work demonstrates the capability of polymerizable systems to aid in the organization of functional polymer–nanoparticle surface structures.

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Light-Directed Organization of Polymer Materials from Photoreactive Formulations

Cited by 10 publications

References 65 publications

Simulations of Structure and Morphology in Photoreactive Polymer Blends under Multibeam Irradiation

Simulations of Structure and Morphology in Photoreactive Polymer Blends under Multibeam Irradiation

Multidirectional Polymer Waveguide Lattices for Enhanced Ultrawide-Angle Light Capture in Silicon Solar Cells

Superhydrophobic Polymer Composite Surfaces Developed via Photopolymerization

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