Dispersion of Nafion Ionomer Aggregates in 1-Propanol/Water Solutions: Effects of Ionomer Concentration, Alcohol Content, and Salt Addition

Mabuchi, Takuya; Huang, Sheng; Tokumasu, Takashi

doi:10.1021/acs.macromol.9b02725

Cited by 43 publications

(72 citation statements)

References 68 publications

(112 reference statements)

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“…[ 267,269 ] Despite the variation in the literature, consensus has built around the simplified model of binary solvents exhibiting rod‐like nano‐aggregates, on the order of 50 nm, [ 273 ] in which the non‐polar backbones constitute the core of the aggregates while the anionic groups sit at the aggregate−solvent interface. [ 273–275 ]…”

Section: Ionomer Distributionmentioning

confidence: 99%

“…Mabuchi et al. [ 274 ] reported that higher ionomer concentration caused the number of Nafion chains in the aggregate and the aggregate size to increase, as shown in Figure 18 . The effect of solvent ratio on aggregate size was also dependent on ionomer concentration, due to competing effects of dielectric constant and hydronium ion distribution.…”

Section: Ionomer Distributionmentioning

confidence: 99%

See 1 more Smart Citation

Engineering Catalyst Layers for Next‐Generation Polymer Electrolyte Fuel Cells: A Review of Design, Materials, and Methods

Suter

Smith

Hack

et al. 2021

Advanced Energy Materials

115

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Polymer electrolyte fuel cells (PEFCs) are a promising replacement for the fossil fuel–dependent automotive and energy sectors. They have become increasingly commercialized in the last decade; however, significant limitations on durability and performance limit their commercial uptake. Catalyst layer (CL) design is commonly reported to impact device power density and durability; although, a consensus is rarely reached due to differences in testing conditions, experimental design, and types of data reported. This is further exacerbated by aspects of CL design such as catalyst support, proton conduction, catalyst, fabrication, and morphology, being significantly interdependent; hence, a wider appreciation is required in order to optimize performance, improve durability, and reduce costs. Here, the cutting‐edge research within the field of PEFCs is reviewed, investigating the effect of different manufacturing techniques, electrolyte distribution, support materials, surface chemistries, and total porosity on power density and durability. These are critically appraised from an applied perspective to inform the most relevant and promising pathways to make and test commercially viable cells. This holistic view of the competing aspects of CL design and preparation will facilitate the development of optimized CLs, especially the incorporation of novel catalyst support materials.

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Section: Ionomer Distributionmentioning

confidence: 99%

Section: Ionomer Distributionmentioning

confidence: 99%

Engineering Catalyst Layers for Next‐Generation Polymer Electrolyte Fuel Cells: A Review of Design, Materials, and Methods

Suter

Smith

Hack

et al. 2021

Advanced Energy Materials

115

View full text Add to dashboard Cite

show abstract

“…The contrasting hydrophobic backbone and hydrophilic sidechains of PFSA have competing preferences in solution, and changing solvent type (including the water:propanol ratio, two common ink solvents) causes PFSA to adopt conformations that reflect this. [5][6][7][8][9][10][11][12][13][14] These different conformations affect the self-assembly of ionomer aggregates and the properties of their films post-drying. [15][16] Furthermore, different conformations will alter how the ionomer adsorbs to catalyst particles.…”

mentioning

confidence: 99%

Probing Ionomer Interactions with Electrocatalyst Particles in Solution

2021

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The interaction between ionomer (ion-conducting polymer) and catalyst particles in porous electrodes of electrochemical energy-conversion devices is a critical yet poorly understood phenomenon that controls device performance. This interaction stems from that in the electrode precursor inks, which also governs porous-electrode morphology during formation. In this letter, we probe the origin of this interaction in solution to unravel the ionomer/particle agglomeration process. Quartz-crystal microbalance studies detail ionomer adsorption (with a range of charge densities) to model surfaces under a variety of solvent environments, and isothermal-titration-calorimetry experiments extract thermodynamic binding information to platinum-and carbon-black nanoparticles. Results reveal that under the conditions tested, ionomer binding to platinum is similar to carbon, suggesting that adsorption to platinum-on-carbon catalyst particles in inks is likely dictated mostly by hydrophobic interactions with the carbon surface. Furthermore, water-rich solvents (relative to propanol) promote ionomer adsorption. Finally, ionomer dispersions change with time, yielding dynamic binding interactions.

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“…Furthermore, Martini has been applied to model ion‐conducting polymeric materials used as ion‐exchange membranes for fuel cell applications. [ 210,220–226 ] Proton‐exchange‐membrane fuel cells use acid polyelectrolytes, such as Nafion, as the membrane material. The membranes are formed by solution‐processing techniques.…”

Section: Example Applicationsmentioning

confidence: 99%

“…In this context, Mabuchi and co‐workers investigated dilute solutions of Nafion ionomers, the initial stage of solution processing: they studied ionomer self‐assembly in mixtures of 1‐propanol and water and probed the effects of ionomer concentration, alcohol content, and inclusion of salt. [ 223,225 ] Goncalves et al. studied instead how cavities nucleate and grow in a hydrated Nafion membrane subject to mechanical deformation, obtaining a nanoscale view on the mechanical properties of such membranes.…”

Section: Example Applicationsmentioning

confidence: 99%

The Martini Model in Materials Science

2021

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The Martini model, a coarse‐grained force field initially developed with biomolecular simulations in mind, has found an increasing number of applications in the field of soft materials science. The model's underlying building block principle does not pose restrictions on its application beyond biomolecular systems. Here, the main applications to date of the Martini model in materials science are highlighted, and a perspective for the future developments in this field is given, particularly in light of recent developments such as the new version of the model, Martini 3.

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Dispersion of Nafion Ionomer Aggregates in 1-Propanol/Water Solutions: Effects of Ionomer Concentration, Alcohol Content, and Salt Addition

Cited by 43 publications

References 68 publications

Engineering Catalyst Layers for Next‐Generation Polymer Electrolyte Fuel Cells: A Review of Design, Materials, and Methods

Engineering Catalyst Layers for Next‐Generation Polymer Electrolyte Fuel Cells: A Review of Design, Materials, and Methods

Probing Ionomer Interactions with Electrocatalyst Particles in Solution

The Martini Model in Materials Science

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