In Situ Observations of Water Production and Distribution in an Operating H2/O2PEM Fuel Cell Assembly Using1H NMR Microscopy

Feindel, Kirk W.; Larocque, Logan P.-A.; Starke, Dieter A.; Bergens, Steven H.; Wasylishen, Roderick E.

doi:10.1021/ja0461116

Cited by 124 publications

(85 citation statements)

References 24 publications

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“…We quickly realized, however, that 1 H NMR microscopy can provide unique information regarding the spatial distribution of water throughout an operating PEMFC. [46] Quantitative measurements of the internal dimensions of the PEMFC are readily obtained by filling the assembly with H 2 O(l). Shown in Figure 6 are two 1 H NMR microscopy images of the water-filled PEMFC obtained using a spin-echo experiment.…”

Section: H Nmr Microscopy Of An Operating Pemfcmentioning

confidence: 99%

“…These methods include electron paramagnetic resonance (EPR) investigations of PEM degradation, [29,30] the construction of PEMFCs using transparent materials, [31][32][33][34][35][36][37][38][39] the use of neutron imaging, [40][41][42][43][44][45] and 1 H NMR microscopy. [46][47][48][49][50] For example, numerous studies have used transparent PEMFCs to investigate the formation of CO 2 (g) in the anode flow field of direct methanol fuel cells [31,32] and the behavior of water in gas diffusion layers. [33] Neutron imaging techniques are inherently sensitive to protons, whilst insensitive to many materials typically used for constructing fuel cells (for example, Al, graphite).…”

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confidence: 99%

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The Use of¹H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

2006

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To understand proton-exchange membrane fuel cells (PEMFCs) better, researchers have used several techniques to visualize their internal operation. This Concept outlines the advantages of using 1H NMR microscopy, that is, magnetic resonance imaging, to monitor the distribution of water in a working PEMFC. We describe what a PEMFC is, how it operates, and why monitoring water distribution in a fuel cell is important. We will focus on our experience in constructing PEMFCs, and demonstrate how 1H NMR microscopy is used to observe the water distribution throughout an operating hydrogen PEMFC. Research in this area is briefly reviewed, followed by some comments regarding challenges and anticipated future developments.

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Section: H Nmr Microscopy Of An Operating Pemfcmentioning

confidence: 99%

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confidence: 99%

The Use of¹H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

2006

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“…However, information about methanol crossover and the related phenomena occurring in the polymer electrolyte membranes (PEMs) of operating DMFCs is scarce, which can be mainly attributed to the difficulty of directly studying the methanol behavior. Recently, nuclear magnetic resonance (NMR) techniques were successfully employed to probe water production and distribution in PEM fuel cells (PEMFC) [4] as well as water and methanol transport in DMFCs.[5] Herein, we present a new type of membrane electrode assembly (MEA) from which a PEM can be extracted free from electrode components, such as catalysts, carbon black, and carbon cloth. Solid-state magic-angle spinning NMR (MAS NMR) studies of this PEM allowedfor the first time-the direct detection of methanol and the reaction intermediates traveling through the PEM during fuel-cell operation.…”

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confidence: 99%

Methanol Behavior in Direct Methanol Fuel Cells

2007

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The direct methanol fuel cell (DMFC) is a promising alternative power source [1] that combines the merits of direct hydrogen/air fuel cells with the advantages of a liquid fuel, such as convenient handling and high energy density. DMFCs that operate at temperatures between 110 and 130 8C are designed for transportation, whereas those operating at lower temperatures ( 60 8C) are intended for use in portable devices.[2] DMFC development is presently focused on optimizing the operating conditions. Nevertheless, a few technical barriers remain to be overcome before successful commercial applications can be achieved.[3] One such barrier is methanol crossover from the anode to the cathode, which not only causes a decrease in the energy efficiency as a result of fuel loss but also affects the fuel cell performance as a consequence of the development of a mixed potential at the cathode. However, information about methanol crossover and the related phenomena occurring in the polymer electrolyte membranes (PEMs) of operating DMFCs is scarce, which can be mainly attributed to the difficulty of directly studying the methanol behavior. Recently, nuclear magnetic resonance (NMR) techniques were successfully employed to probe water production and distribution in PEM fuel cells (PEMFC) [4] as well as water and methanol transport in DMFCs.[5] Herein, we present a new type of membrane electrode assembly (MEA) from which a PEM can be extracted free from electrode components, such as catalysts, carbon black, and carbon cloth. Solid-state magic-angle spinning NMR (MAS NMR) studies of this PEM allowedfor the first time-the direct detection of methanol and the reaction intermediates traveling through the PEM during fuel-cell operation.An MEA consisting of a triple-layer PEM (Nafion 117) was prepared for the DMFC by using PtRu/C and Pt/C as the anode and cathode catalysts, respectively. The MEA configuration and the sampling procedure for the MAS NMR experiments are shown schematically in Figure 1. The procedure is described in the Experimental Section, and more details are available in the Supporting Information. The triple-layer PEM DMFC exhibited a current density that was about 80 % of that of a standard cell (operating with 2 m methanol and a single-layer PEM), and the maximum potential of the triple-layer cell was about 100 mV lower than that of the standard cell (Figure 2). This reduction in current density and potential can be ascribed to the increased resistance of the triple-layer PEM, which is three times thicker (0.54 mm) than a single-layer membrane (0.18 mm). Figure 3 shows the 13 C MAS NMR spectrum of the middle PEM layer of a DMFC, which was extracted after operation of the fuel cell using a 2 m aqueous solution of 13 CH 3 OH (for at least 15 min). Previous to this operation, the fuel cell was run for 2 days (using 2 m CH 3 OH) at 350 mV, thereby achieving a current density of about 50 mA cm À2 . The dominant 13 C signal (observed at d = 49 ppm) corresponds to methanol species in the PEM, which are crossing over to the c...

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“…Similarly, Zhang et al [66] reported a direct water content measurement across the Nafion membrane in an operational PEMFC, employing double half k-space spin echo single point imaging techniques. Feindel and co-workers [70][71][72][73] performed systematic in-situ investigations of in-plane water distributions and accumulation in the PEM. For example, 1 H NMR microscopy was employed to investigate the influence of co-versus counter-flow gas configurations on the in-plane distribution of water in PEM of the operating PEMFC.…”

Section: Nuclear Magnetic Resonance (Nmr) Imagingmentioning

confidence: 99%

A Review of Water Management in Polymer Electrolyte Membrane Fuel Cells

2009

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At present, despite the great advances in polymer electrolyte membrane fuel cell (PEMFC) technology over the past two decades through intensive research and development activities, their large-scale commercialization is still hampered by their higher materials cost and lower reliability and durability. In this review, water management is given special consideration. Water management is of vital importance to achieve maximum performance and durability from PEMFCs. On the one hand, to maintain good proton conductivity, the relative humidity of inlet gases is typically held at a large value to ensure that the membrane remains fully hydrated. On the other hand, the pores of the catalyst layer (CL) and the gas diffusion layer (GDL) are frequently flooded by excessive liquid water, resulting in a higher mass transport resistance. Thus, a subtle equilibrium has to be maintained between membrane drying and liquid water flooding to prevent fuel cell degradation and guarantee a high performance level, which is the essential problem of water management. This paper presents a comprehensive review of the state-of-the-art studies of water management, including the experimental methods and modeling and simulation for the characterization of water management and the water management strategies. As one important aspect of water management, water flooding has been extensively studied during the last two decades. Herein, the causes, detection, effects on cell performance and mitigation strategies of water flooding are overviewed in detail. In the end of the paper the emphasis is given to: (i) the delicate equilibrium of membrane drying vs. water flooding in water management; (ii) determining which phenomenon is principally responsible for the deterioration of the PEMFC performance, the flooding of the porous electrode or the gas

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In Situ Observations of Water Production and Distribution in an Operating H₂/O₂PEM Fuel Cell Assembly Using¹H NMR Microscopy

Cited by 124 publications

References 24 publications

The Use of¹H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

The Use of¹H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

Methanol Behavior in Direct Methanol Fuel Cells

A Review of Water Management in Polymer Electrolyte Membrane Fuel Cells

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In Situ Observations of Water Production and Distribution in an Operating H2/O2PEM Fuel Cell Assembly Using1H NMR Microscopy

Cited by 124 publications

References 24 publications

The Use of1H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

The Use of1H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

Methanol Behavior in Direct Methanol Fuel Cells

A Review of Water Management in Polymer Electrolyte Membrane Fuel Cells

Contact Info

Product

Resources

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In Situ Observations of Water Production and Distribution in an Operating H₂/O₂PEM Fuel Cell Assembly Using¹H NMR Microscopy

The Use of¹H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells

The Use of¹H NMR Microscopy to Study Proton‐Exchange Membrane Fuel Cells