Radiation Grafted Ion-Conducting Membranes: The Influence of Variations in Base Film Nanostructure

Sproll, Véronique; Nagy, Gergely; Gasser, Urs; Embs, Jan Peter; Obiols‐Rabasa, Marc; Schmidt, Thomas J.; Gubler, Lorenz; Balog, Sandor

doi:10.1021/acs.macromol.6b00180

Cited by 34 publications

(43 citation statements)

References 65 publications

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“…This is a dramatic demonstration of the findings by Sproll et al related to the development of RG-proton-exchange membranes (RG-PEM), 12 who reported that conductivities, water uptakes, and resulting fuel cell (PEMFC) performances strongly depend on the micro-structure of the ETFE-base films used. The use of nominally identical base ETFE films (from two suppliers), differing only in microstructure, resulted in critical differences in the final membranes: larger crystalline sizes led to enhanced RG-PEM conductivities and durabilities of the resulting PEMFCs.…”

supporting

confidence: 56%

Radiation-grafted anion-exchange membranes: the switch from low- to high-density polyethylene leads to remarkably enhanced fuel cell performance

Wang

Peng

Mustain

et al. 2019

Energy Environ. Sci.

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216

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supporting

confidence: 56%

Radiation-grafted anion-exchange membranes: the switch from low- to high-density polyethylene leads to remarkably enhanced fuel cell performance

Wang

Peng

Mustain

et al. 2019

Energy Environ. Sci.

256

216

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“…The corresponding characteristic distances are quite similar for both PEMs, which reflects that the swelling of the base film is due to the grafted polymer . This characteristic distance is, however, slightly larger for the L‐PEM (approx.…”

Section: Resultsmentioning

confidence: 76%

“…15 wt% with an average crystallite size of approx. 9 nm . To enhance scattering from the ionic groups located exclusively in the grafted domains, both PEMs were converted into the Cs‐salt form as outlined in ref .…”

Section: Resultsmentioning

confidence: 99%

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Scaling the Graft Length and Graft Density of Irradiation‐Grafted Copolymers

Nagy

Sproll

Gasser

et al. 2018

Macro Chemistry & Physics

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Graft CopolymersIrradiation-induced graft copolymerization is often the easiest route to combine the functionality of two polymers and, furthermore, the average composition of the copolymer is straightforward to control. However, control of the graft length and the graft density is more difficult and has been considered to be infeasible. To test the hypothesis that the graft density and graft length may be increased or decreased via increasing or decreasing the dose of irradiation and graft level, polymer electrolytes are characterized in terms of water sorption, proton conductivity, and nanostructure. Based on the premise that graft density and graft length define ion transport and phase segregation, impedance spectroscopy and small-angle scattering support the hypothesis. The method therefore represents a novel degree of freedom in the design and synthesis of radiation grafted copolymers. 2 of 7) www.advancedsciencenews.com www.mcp-journal.de (

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“…This radiation technique allows us to introduce various functional grafted polymers directly bonded to the main chains of polymer substrates, while the inherent characteristics of the polymer substrates such as thermal stability, mechanical strength, and crystallinity are still retained. Morphology of the graft‐type PEMs prepared by the above radiation grafting technique has been intensively investigated using the small‐angle scattering methods with various matrix polymers of poly(tetrafluoroethylene) (PTFE), poly(ether ether ketone) (PEEK), poly(vinylidene fluoride) (PVDF), and poly(ethylene‐ co ‐tetrafluoroethylene) (ETFE) . Consequently, various general features have been well‐established as follows.…”

Section: Introductionmentioning

confidence: 99%

SAXS Investigation on Morphological Change in Lamellar Structures During Propagation Steps of Graft‐Type Polymer Electrolyte Membranes for Fuel Cell Applications

Tap

Nguyen

Zhao³

et al. 2019

Macro Chemistry & Physics

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their advantages over other fuel cells in terms of the clean and efficient power generation and lower operating temperature. [1] They are expected to reduce the fossil fuel consumption, which is believed to be the primary sources causing the climate change. PEM, which consists of super acid groups (i.e., sulfonic acid), has been considered as one of the key components in achieving the high fuel cell performance because of its unique fuel cell properties such as ionic conductance, mechanical strength, and thermal and chemical stabilities. When a dry PEM is immersed in water, the hydrophilic chains with sulfonic ion groups can absorb water and consequently form the interconnected ion channels inside the hydrated regions. The macro and microphase separations, viz., crystalline morphologies, conducting layers (ion channels), characteristic domain sizes, and the connection and distribution of the ionic groups and water in the conducting layers and around the crystalline phases are believed to play an important role in the conductivity and mechanical integrity of the PEMs. [2][3][4] Currently, the main challenges to improve the conductivity and mechanical strength of the PEMs are the lack of detailed informationThe changes of the lamellar periods (L 1D ), thickness of lamellar crystals (L c ), and amorphous layers (L a ) within the stacked lamellae of poly(styrenesulfonic acid)-grafted poly(ethylene-co-tetrafluoroethylene) polymer electrolyte membranes (ETFE-PEMs), induced by the preparation and water-absorbing steps are investigated using the small-angle X-ray scattering method. The L 1D values of all the samples quickly increase at a grafting degree (GD) range of less than 19% and then level off. The solvent-induced recrystallization is observed at the early stage of grafting (GD < 10%) and at successive sulfonation and hydration steps. The L 1D , L a , and L c of dry and hydrated PEMs show similar values at higher GD ranges (>34%), leading to the conclusion that most water molecules in the PEMs with higher GDs exist at the outside of the lamellar stacks. Accordingly, for the PEMs with low GD (<19%), all the hydrophilic graft-polymers (ion-channels) locate in the lamellar stacks and are strongly restricted by lamellar crystalline layers, which suppress the swelling of the PEMs. The unique lamellar structures of ETFE-PEMs characterized by L a and L c are well connected with the high conductance and mechanical properties of the membranes, and are suitable for fuel cell applications.

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Radiation Grafted Ion-Conducting Membranes: The Influence of Variations in Base Film Nanostructure

Cited by 34 publications

References 65 publications

Radiation-grafted anion-exchange membranes: the switch from low- to high-density polyethylene leads to remarkably enhanced fuel cell performance

Radiation-grafted anion-exchange membranes: the switch from low- to high-density polyethylene leads to remarkably enhanced fuel cell performance

Scaling the Graft Length and Graft Density of Irradiation‐Grafted Copolymers

SAXS Investigation on Morphological Change in Lamellar Structures During Propagation Steps of Graft‐Type Polymer Electrolyte Membranes for Fuel Cell Applications

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