Jiwoo Choi scite author profile

HIGHLIGHTS • Moth-eye structured polydimethylsiloxane (PDMS) films with different sizes were fabricated to improve the efficiency of perovskite solar cells. • The PDMS with 300-nm moth-eye films significantly reduced light reflection at the front of the glass and therefore enhanced the solar cell efficiency of ~ 21%. • The PDMS with 1000-nm moth-eye films exhibited beautiful coloration. ABSTRACT Large-area polydimethylsiloxane (PDMS) films with variably sized moth-eye structures were fabricated to improve the efficiency of perovskite solar cells. An approach that incorporated photolithography, bilayer PDMS deposition and replication was used in the fabrication process. By simply attaching the moth-eye PDMS films to the transparent substrates of perovskite solar cells, the optical properties of the devices could be tuned by changing the size of the moth-eye structures. The device with 300-nm moth-eye PDMS films greatly enhanced power conversion efficiency of ~ 21% due to the antireflective effect of the moth-eye structure. Furthermore, beautiful coloration was observed on the 1000-nm moth-eye PDMS films through optical interference caused by the diffraction grating effect. Our results imply that moth-eye PDMS films can greatly enhance the efficiency of perovskite solar cells and building-integrated photovoltaics.

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Multifunctional Nafion/CeO₂ Dendritic Structures for Enhanced Durability and Performance of Polymer Electrolyte Membrane Fuel Cells

Choi

Yeon

Yook

et al. 2021

ACS Appl. Mater. Interfaces

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The development of a novel approach to achieve high-performance and durable fuel cells is imperative for the further commercialization of proton-exchange (or polymer electrolyte) membrane fuel cells (PEMFCs). In this work, multifunctional dendritic Nafion/CeO 2 structures were introduced onto the cathode side of the interface between a membrane and a catalyst layer through electrospray deposition. The dendritic structures enlarged the interfacial contact area between the membrane and the catalyst layer and formed microscale voids between the catalyst layer and gas diffusion medium. This improved the PEMFC performance through the effective utilization of the catalyst and enhanced mass transport of the reactant. Especially, under lowhumidity conditions, the hygroscopic effect of CeO 2 nanoparticles also boosted the power density of PEMFCs. In addition to the beneficial effects on the efficiency of the PEMFC, the incorporation of CeO 2 , widely known as a radical scavenger, effectively mitigated the free-radical attack on the outer surface of the membrane, where chemical degradation is initiated by radicals formed during PEMFC operation. These multifunctional effects of the dendritic Nafion/CeO 2 structures on PEMFC performance and durability were investigated using various in situ and ex situ measurement techniques.

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Membrane/Electrode Interface Design for Effective Water Management in Alkaline Membrane Fuel Cells

Jang

Her

Kim

et al. 2019

ACS Appl. Mater. Interfaces

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The recent development of ultrathin anion exchange membranes and optimization of their operating conditions have significantly enhanced the performance of alkaline-membrane fuel cells (AMFCs); however, the effects of the membrane/electrode interface structure on the AMFC performance have not been seriously investigated thus far. Herein, we report on a high-performance AMFC system with a membrane/electrode interface of novel design. Commercially available membranes are modified in the form of well-aligned line arrays of both the anode and cathode sides by means of a solvent-assisted molding technique and sandwich-like assembly of the membrane and polydimethylsiloxane molds. Upon incorporating the patterned membranes into a single-cell system, we observe a significantly enhanced performance of up to ∼35% compared with that of the reference membrane. The enlarged interface area and reduced membrane thickness from the line-patterned membrane/electrode interface result in improved water management, reduced ohmic resistance, and effective utilization of the catalyst. We believe that our findings can significantly contribute further advancements in AMFCs.

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Guided cracking of electrodes by stretching prism-patterned membrane electrode assemblies for high-performance fuel cells

Ahn

Jang

Cho

et al. 2018

Sci Rep

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Guided cracks were successfully generated in an electrode using the concentrated surface stress of a prism-patterned Nafion membrane. An electrode with guided cracks was formed by stretching the catalyst-coated Nafion membrane. The morphological features of the stretched membrane electrode assembly (MEA) were investigated with respect to variation in the prism pattern dimension (prism pitches of 20 μm and 50 μm) and applied strain (S ≈ 0.5 and 1.0). The behaviour of water on the surface of the cracked electrode was examined using environmental scanning electron microscopy. Guided cracks in the electrode layer were shown to be efficient water reservoirs and liquid water passages. The MEAs with and without guided cracks were incorporated into fuel cells, and electrochemical measurements were conducted. As expected, all MEAs with guided cracks exhibited better performance than conventional MEAs, mainly because of the improved water transport.

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Jiwoo Choi

A large‐scale meta‐analytic atlas of mental health problems prevalence during the COVID‐19 early pandemic

Moth-eye Structured Polydimethylsiloxane Films for High-Efficiency Perovskite Solar Cells

Multifunctional Nafion/CeO₂ Dendritic Structures for Enhanced Durability and Performance of Polymer Electrolyte Membrane Fuel Cells

Membrane/Electrode Interface Design for Effective Water Management in Alkaline Membrane Fuel Cells

Guided cracking of electrodes by stretching prism-patterned membrane electrode assemblies for high-performance fuel cells

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Jiwoo Choi

A large‐scale meta‐analytic atlas of mental health problems prevalence during the COVID‐19 early pandemic

Moth-eye Structured Polydimethylsiloxane Films for High-Efficiency Perovskite Solar Cells

Multifunctional Nafion/CeO2 Dendritic Structures for Enhanced Durability and Performance of Polymer Electrolyte Membrane Fuel Cells

Membrane/Electrode Interface Design for Effective Water Management in Alkaline Membrane Fuel Cells

Guided cracking of electrodes by stretching prism-patterned membrane electrode assemblies for high-performance fuel cells

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Product

Resources

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Multifunctional Nafion/CeO₂ Dendritic Structures for Enhanced Durability and Performance of Polymer Electrolyte Membrane Fuel Cells