Relationship between the Proton Conductive Performance and Water Uptake Ratio on a Filler-Filled Polymer Electrolyte Membrane

Saito, Takaaki; Nohara, Tomohiro; Tabata, Keisuke; Nakazaki, Haruki; Makino, Tsutomu; Matsuo, Yoshimasa; Sato, Keisuke; Abadie, Colette; Masuhara, Akito

doi:10.1021/acs.energyfuels.2c02527

Cited by 9 publications

(16 citation statements)

References 43 publications

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“…Since SDT has two sulfonic acid groups per repeat unit, the number of sulfonic acid groups in the membrane after cross-linking would increase. This results in a relatively larger water uptake and forms large hydrophilic domains that may facilitate proton transfer, resulting in high proton conductivity even under very low RH conditions [ 36 ]. As a result, SDT-CSPAES membranes exhibited high proton conductivity despite the inevitable reduction in the chain mobility by the formation of the cross-linked structure.…”

Section: Resultsmentioning

confidence: 99%

Cross-Linked Sulfonated Poly(arylene ether sulfone) Membrane Using Polymeric Cross-Linkers for Polymer Electrolyte Membrane Fuel Cell Applications

et al. 2022

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Cross-linked membranes for polymer electrolyte membrane fuel cell application are prepared using highly sulfonated poly(arylene ether sulfone) (SPAES) and polymeric cross-linkers having different hydrophilicities by facile in-situ casting and heating processes. From the advantage of the cross-linked structures made with the use of polymeric cross-linkers, a stable membrane can be obtained even though the polymer matrix with a very high degree of sulfonation was used. In particular, hydrophilic cross-linker is found to be effective in improving physicochemical properties of the cross-linked membranes and at the same time showing reasonable proton conductivity. Accordingly, membrane electrode assembly made from the cross-linked membrane prepared by using hydrophilic polymeric cross-linker exhibits outstanding cell performance under high temperature and low relative humidity conditions (e.g., maximum power density of 176.4 mW cm−2 at 120 °C and 40% RH).

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Section: Resultsmentioning

confidence: 99%

Cross-Linked Sulfonated Poly(arylene ether sulfone) Membrane Using Polymeric Cross-Linkers for Polymer Electrolyte Membrane Fuel Cell Applications

et al. 2022

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“…The shape selective nanoparticle reduces not only the extent of composite interaction between polymer chains but also resist the local crystallization effect into polymer network . Oxygen vacant filler improve the interfacial strength and ionic conductivity of composite polymer. , The electrolyte cation are attracted on the nanostructured silica surface (Si–OH) result in enhancement of free density of the redox-active anion which further increases the mobility of electrolyte active ion into the gel electrolyte . The conducting PANI elevates anionic mobility into the electrolyte by increasing the content of the amorphous state into polymeric component.…”

Section: Structural Variation Of Electrolyte Groups Composite Interac...mentioning

confidence: 99%

Review on Functional Electrolyte, Redox Polymers, and Solar Conversions in 3G Emerging Photovoltaic Technologies: Progress and Outlook

Kumar,

Maiti

2023

Energy Fuels

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Abundant solar energy has transformed the present solar photovoltaics owing to its rapid conversion into electrical energy without deteriorating ecosystem. Third generation (3G) energy conversion devices reveal utilization of photosensitizer, i.e., organic dye, quantum dots, and perovskite as functional absorbing materials to transform solar energy. Functional polymers are key ingredients (fuels) for the development of suitable redox potential and high temperature or humidity resistive charge transport medium. Electrolyte accelerates the photovoltaic reversible reaction (hole conduction) through exposure of a minimum energy barrier between the photoanode and cathode. Redox-active polymer enhances electrolyte uptake efficiency, ionic conductivity, and dimensional stability of solar device. Various electrolytes exhibit different functional activities due to their different redox energy. The functionalized polymer bears appropriate HOMO–LUMO energetics and low activation energy, which could adjust different photosensitizer with better compatibility. Therefore, the redox polymer percolates a redox couple at a photoexcited sensitizer through control of undesired reactions. It plays the important role of ion and electron transport mediator via expanding suitable interfacial energetics and band structure for photovoltaic reaction. The polymeric pendant groups (chemical environments) preserve electrolyte couples through reducing wettability and thus immobilize the active density of electrolyte anions for photovoltaic reactions. Thus, the polymer improves reversibility due to interfacial compatibility, electrolyte filtration effect, and synergistic stabilization. The present review focuses on polymer-derived functional electrolytes, photosensitizer–polymer interface, thermodynamic interactions, and power conversion efficiencies of 3G photovoltaic devices. Functional polymers open an avenue for the development of stable and efficient photovoltaic reactions at low cost based dyes, quantum dots, and perovskite-sensitized solar conversion systems.

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“…Recently, we fabricated PEMs by combining polymer-coated nanoparticles with three binders. 26 The polymer-coated nanoparticles were composed of cellulose nanocrystals (CNC) as a core and coated with copolymer of poly(vinylphosphonic acid) (PVPA) and polystyrene (PS) (PVPA-b-PS) as a shell. Then, PVPA-b-PScoated CNC (CNC@PVPA-b-PS) were kneaded with poly-(methyl methacrylate) (PMMA), polycarbonate (PC), and PS, resulting in each PEM being fabricated.…”

Section: ■ Introductionmentioning

confidence: 99%

Highly Proton Conductive Membranes Based on Poly(vinylphosphonic acid)-Coated Cellulose Nanocrystals and Cellulose Nanofibers for Polymer Electrolyte Fuel Cells

Saito,

Matsuo,

Tabata

et al. 2024

Energy Fuels

Self Cite

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Polymer electrolyte membranes (PEMs) are frequently composed of perfluorosulfonic acid polymers (PFSAs) and are used in polymer electrolyte fuel cells (PEFCs). However, PFSAs encounter obstacles such as intense acidity, environmental impact, and high cost. Previous studies have attempted to achieve high proton conductivity in low-acid materials by constructing precise conduction pathways. In addition, nanocellulose is a promising new membrane material for PEFCs with a much lower environmental impact and cost than PFSA. In this study, nanocellulose-based membranes were produced by using polymer-coated cellulose nanocrystals (CNC), and cellulose nanofibers (CNF) as a binder. The nanocellulose-based membranes demonstrated a maximum conductivity of 9.2 × 10 −2 S/cm, which was comparable to that of PFSAs, even though approximately 80% of the components were nanocellulose. This could be attributed to the creation of highly proton-conducting pathways at the interface between the hydrophilic layers of CNC-polymer, and the water uptake and retention properties of CNF. This result suggests that nanocellulose presents a high potential substitute for PFSAs and serves as a pivotal component in the forthcoming age of environmentally sustainable PEMs. In addition, nanocellulose exhibits exceptional features that make it suitable for use as a binder in secondary batteries.

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Relationship between the Proton Conductive Performance and Water Uptake Ratio on a Filler-Filled Polymer Electrolyte Membrane

Cited by 9 publications

References 43 publications

Cross-Linked Sulfonated Poly(arylene ether sulfone) Membrane Using Polymeric Cross-Linkers for Polymer Electrolyte Membrane Fuel Cell Applications

Cross-Linked Sulfonated Poly(arylene ether sulfone) Membrane Using Polymeric Cross-Linkers for Polymer Electrolyte Membrane Fuel Cell Applications

Review on Functional Electrolyte, Redox Polymers, and Solar Conversions in 3G Emerging Photovoltaic Technologies: Progress and Outlook

Highly Proton Conductive Membranes Based on Poly(vinylphosphonic acid)-Coated Cellulose Nanocrystals and Cellulose Nanofibers for Polymer Electrolyte Fuel Cells

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