Carbon Support Microstructure Impact on High Current Density Transport Resistances in PEMFC Cathode

Ramaswamy, Nagappan; Gu, Wenbin; Ziegelbauer, Joseph M.; Kumaraguru, Swami

doi:10.1149/1945-7111/ab819c

Cited by 149 publications

(213 citation statements)

References 47 publications

Supporting

Mentioning

212

Contrasting

Order By: Relevance

“…More interestingly, this catalyst also demonstrates high power/performance compared with the state-of-the-art electrocatalysts, Pt(20 wt%)NPs/VC (JM), Pt(40 wt%)NPs/Hi-spec (JM), and Pt(50 wt%)NPs/HSAC (Tanaka), which is very important in reducing the size and cost of the fuel cell stack. [49] Last but not the least, it is worth noting that in this study, neither the amount of g-CN nor the macroporosity of the MPC support were optimized, thus it is likely that the electrocatalytic performance of g-CN@MPC-supported Pt NW catalysts can still be further increased. Furthermore, Pt metal and Pt alloys (e.g., Pt 3 Ni) with other morphologies (e.g., Nanoframe) which have demonstrated ultrahigh electrocatalytic activity toward the ORR [4,50] can be incorporated into g-CN@MPC to further enhance the electrocatalytic activity and electrochemical stability of this electrocatalyst approach.…”

Section: Resultsmentioning

confidence: 93%

Dense Pt Nanowire Electrocatalyst for Improved Fuel Cell Performance Using a Graphitic Carbon Nitride‐Decorated Hierarchical Nanocarbon Support

Fang

Daniel

Bonakdarpour

et al. 2021

Small

View full text Add to dashboard Cite

electric vehicles, distributed home power generators, and power sources for small and portable electronics. [1][2][3][4] Early commercial products are now available for a number of applications (e.g., backup power and buses); however, further cost reduction of components and simplification of technology are required for a larger market penetration. Among these requirements, reduction of Pt content of the oxygen reduction reaction (ORR) electrode and overall improvements in the performance of membrane electrode assemblies (MEAs) are among the highest priorities in the development and commercialization of hydrogen-fed PEMFCs. [5][6][7][8] Although to date, very attractive ORR activities determined by rotating disk electrode (RDE) measurements have been reported for some new electrocatalysts, only very few electrocatalysts have demonstrated promising fuel cell power performance and electrochemical stability in practical PEMFC applications. [9][10][11] The use of supported electrocatalysts is a proven and an efficient strategy to reduce the Pt usage and improve the electrocatalytic activity of Pt-based electrocatalysts, [12][13][14][15][16] and for this purpose, a large selection of porous materials has been investigated as electrocatalyst supports. These supports mainly include carbonaceous materials, such as carbon black (Vulcan XC-72R, denoted as VC), [2,17] carbon nanotubes, [18] multi modal porous carbon (MPC), [19,20] hollow macro porous core-mesoporous shell carbon spheres, [21] and ordered SnO 2 @C. [22] Commonly available carbon-supported Pt catalysts typically consist of Pt nanoparticles (NPs) with a catalyst content of 20-60 wt% supported onto commercial high surface area carbon particles, mainly VC. Electrocatalysts with a lower Pt wt% content lead to thicker electrode catalyst layers in order to maintain the same catalyst mass in the catalyst layer of the electrode. Using a lower wt% Pt content, however, leads to limitations in the mass transport of the reactants (H 2 fuel and O 2 /air) to the electrode and removal of the product water away from the electrode. Therefore, development of highly efficient Pt-based catalysts with a high Pt content (≥40 wt%) is of particular importance due to the enhanced mass transport in the An innovative strategy is presented to engineer supported-Pt nanowire (NW) electrocatalysts with a high Pt content for the cathode of hydrogen fuel cells. This involves deposition of graphitic carbon nitride (g-CN) onto 3D multimodal porous carbon (MPC) (denoted as g-CN@MPC) and using the g-CN@MPC as an electrocatalyst support. The protective coating of g-CN on the MPC provides good stability for the electrocatalyst support against electrochemical oxidation, and also enhances oxygen adsorption and provides additional active sites for the oxygen reduction reaction. Compared with commercial carbon black Vulcan XC-72R (denoted as VC) support material, the larger hydrophobic surface area of the g-CN@MPC enables the supported high-content Pt NWs to disperse uniformly on the support. In addit...

show abstract

Section: Resultsmentioning

confidence: 93%

Dense Pt Nanowire Electrocatalyst for Improved Fuel Cell Performance Using a Graphitic Carbon Nitride‐Decorated Hierarchical Nanocarbon Support

Fang

Daniel

Bonakdarpour

et al. 2021

Small

View full text Add to dashboard Cite

show abstract

“…GrC carbon support (MEA 1 and MEA 2) has almost no internal porosity, which results in a low total surface area, where all the Pt particles distribute on the surface of the support. For MEA 3, according to Nagappan et al, 26 high surface area carbon (HSC) support has around 3-5 times higher total surface area than Vulcan carbon support due to its high internal porosity. Figure 7a shows the effective ionic conductivities for MEA 1 and MEA 2 (properties defined in Table I).…”

Section: Resultsmentioning

confidence: 99%

“…At low RH, MEA 3 with the HSC support showed lower effective ionic conductivity. It was shown recently by Ramaswamy et al 26 that surface area of smaller meso-pores (> 8 nm) of the carbon support determines the continuity and uniformity of the ionomer distribution in the catalyst layer. The GrC carbon support in MEA 2 has less to no meso-pores compared to the HSC used in MEA 3, which results in a larger effective ionic conductivity of MEA 2.…”

Section: Resultsmentioning

confidence: 99%

Interpreting Ionic Conductivity for Polymer Electrolyte Fuel Cell Catalyst Layers with Electrochemical Impedance Spectroscopy and Transmission Line Modeling

Liu

Sabarirajan

et al. 2021

J. Electrochem. Soc.

View full text Add to dashboard Cite

A cathode catalyst layer containing optimally distributed ionomer is critical to reduce the platinum loading and increase its utilization in polymer electrolyte fuel cells. Here, electrochemical impedance spectroscopy (EIS) was used to measure effective ionic conductivity of pseudo catalyst layers (PCLs) at a relative humidity (RH) range of 50%-120%. These results are compared to previous work using the hydrogen pump (HP) method. EIS effective ionic conductivity results reported here are higher than those from the HP because in the HP set-up ionic pathways must be effectively connected through the PCL to be counted, whereas in the EIS measurement, ionomer segments that are in contact with the membrane but are not effectively connected all the way through the PCL can be detected. Double layer capacitances and effective ionic conductivities of Pt/C catalyst layers with various supports and ionomer to carbon (I/C) ratios were studied. High surface area carbon support resulted in a lower effective ionic conductivity compared to the graphitized carbon support due to worse ionomer dispersion. Effective ionic conductivities of Pt/C layers were compared to that of PCLs. On average, effective ionic conductivities of Pt/C layers were higher than PCLs because of possible carbon agglomeration within the PCLs.

show abstract

“…However, this location ensures that the Pt surface is in contact with the ionomer, leading to adsorption of sulfonic acid groups and poisoning effects. 13,14 Based on such observations, Harzer et al 13 suggested that an ideal catalyst ought to have most of the Pt particles outside for good mass transport, while having a small fraction of internal Pt to increase total mass activity. Similar results have also been obtained by other researchers.…”

mentioning

confidence: 99%

Effects of PEMFC Operational History under Dry/Wet Conditions on Additional Voltage Losses due to Ionomer Migration

Đào

Peitl

et al. 2020

J. Electrochem. Soc.

View full text Add to dashboard Cite

Over its lifetime in a fuel cell electric vehicle, a polymer electrolyte membrane fuel cell inevitably suffers from certain duration of dry operational conditions, where significant performance losses of the fuel cell take place. In this study, we investigate the activity changes of the fuel cell after a prolonged degradation protocol under dry operational condition, followed by various recovery procedures under wet conditions. The utilization of diluted air on the cathode side is found to be advantageous for the recovery due to the superior heat and water management. This more efficient recovery protocol allows the deconvolution of reversible and irreversible voltages losses after dry operations. A subsequent mechanistic study reveals an irreversible decrease of the effective ionomer coverage on the catalyst particles, while the proton conductivity of the catalyst layer drops. These observations point towards ionomer structural changes caused by the dry conditions. This is confirmed by post-mortem analysis via scanning electron microscope, showing clearly that ionomer redistributes and migrates, an additional mechanism which leads to the performance losses. Overall, the degradation mechanisms seem to be mitigated by higher ionomer content in the catalyst layer, while the investigated surface modification of carbon support shows minor sensitivities.

show abstract

Carbon Support Microstructure Impact on High Current Density Transport Resistances in PEMFC Cathode

Cited by 149 publications

References 47 publications

Dense Pt Nanowire Electrocatalyst for Improved Fuel Cell Performance Using a Graphitic Carbon Nitride‐Decorated Hierarchical Nanocarbon Support

Dense Pt Nanowire Electrocatalyst for Improved Fuel Cell Performance Using a Graphitic Carbon Nitride‐Decorated Hierarchical Nanocarbon Support

Interpreting Ionic Conductivity for Polymer Electrolyte Fuel Cell Catalyst Layers with Electrochemical Impedance Spectroscopy and Transmission Line Modeling

Effects of PEMFC Operational History under Dry/Wet Conditions on Additional Voltage Losses due to Ionomer Migration

Contact Info

Product

Resources

About