Impact of Glass Corrosion on the Electrocatalysis on Pt Electrodes in Alkaline Electrolyte

Mayrhofer, Karl Johann Jakob; Wiberg, Gustav K. H.; Arenz, Matthias

doi:10.1149/1.2800752

Cited by 148 publications

(161 citation statements)

References 30 publications

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“…All electrochemical measurements were conducted in an in house developed three-compartment electrochemical cell made out of Teflon [36,37]. A saturated calomel electrode (SCE), separated from the working electrode compartment by a membrane, was used as the reference electrode [38].…”

Section: Methodsmentioning

confidence: 99%

On the oxygen reduction reaction in phosphoric acid electrolyte: Evidence of significantly increased inhibition at steady state conditions

Deng

Wiberg

Zana

et al. 2016

Electrochimica Acta

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In the presented work, we investigate the oxygen reduction reaction (ORR) in half-cell measurements employing different electrolytes. The aim is to compare the ORR inhibition due to anion adsorption at transient as well as steady state conditions. It is found that the ORR inhibition at the platinum -phosphoric acid electrolyte interface is a relative slow, time dependent process. The major inhibition is not observed in transient polarization curves but only under steady state 2 conditions. This observation is in contrast to the typical ORR inhibition due to anion adsorption as observed for example in sulfuric acid electrolyte. In sulfuric acid the inhibition is fast and then stays more or less constant in time. As a consequence of our findings, common transient measurements of the ORR activity might not be sufficient to investigate suitable mitigation strategies for the ORR inhibition in phosphoric acid electrolyte. Such strategies need to take steady state conditions into account.In order to explain the slow ORR inhibition in phosphoric acid electrolyte, two possible explanations are discussed. Either the adsorption of phosphate is a slow, complex process, where a fast adsorption step is followed by a consecutive filling of the surface, or a mass transfer barrier develops at the polarized phosphoric acid -electrode interface. The latter might be the viscoelectric effect that is known from colloidal science.

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Section: Methodsmentioning

confidence: 99%

On the oxygen reduction reaction in phosphoric acid electrolyte: Evidence of significantly increased inhibition at steady state conditions

Deng

Wiberg

Zana

et al. 2016

Electrochimica Acta

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“…The choice of PTFE as opposed to glass for the measurements in alkaline media was motivated by the detrimental effects of glass corrosion products on the HOR/HER-kinetics of Pt. 30 The PTFE cell was embedded in a stainless steel jacket connected to a calibrated thermostat (Julabo Labortechnik GmbH, Seelbach, Germany) at 293 K, and it was closed with a four-necked glass cover which has no contact to electrolyte. The glass cell used with acid electrolytes also had four necks, and thus both setups consisted of similar working, reference and counter electrodes, along with a gas bubbler that allowed for gas blanketing above the surface of the electrolyte or direct bubbling through a fluorinated ethylene propylene (FEP) tube.…”

Section: Methodsmentioning

confidence: 99%

Bulk-Palladium and Palladium-on-Gold Electrocatalysts for the Oxidation of Hydrogen in Alkaline Electrolyte

Henning

Herranz

Gasteiger

2014

J. Electrochem. Soc.

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The commercial feasibility of alkaline-exchange membrane fuel cells and electrolyzers passes by the development of hydrogen oxidation and evolution reaction (HOR/HER) catalysts featuring an activity and/or cost advantage over platinum, which remains the most active metal for these processes. Among these alternatives, Pd appears as a promising candidate, since its price is typically 2-3 fold lower than that of Pt. With this motivation, the first section of this study displays our attempts at quantifying the kinetic parameters of the HOR/HER on bulk Pd in 0.1 M NaOH, which were prevented by the simultaneous absorption of hydrogen into bulk palladium. We succeeded at circumventing this issue by depositing Pd-adlayers on a polycrystalline Au-substrate by galvanic displacement of underpotentially-deposited Cu or by electrochemical plating of Pd 2+ . The resulting surfaces appear to consist of three-dimensional Pd-structures of an unknown thickness that we believe to scale with the palladium coverage, θ Pd/Au . This last parameter is inversely proportional to the HOR/HER-activity of the Pd-on-Au surfaces, in agreement with numerous theoretical and experimental studies in acid media that correlate this effect to the tensile strain induced by the Au-substrate on the Pd-lattice. Proton-exchange membrane fuel cells (PEMFCs) fueled with hydrogen stored at 700 bar can attain energy densities in excess of 200 Wh · kg −1 (on a PEMFC system basis), making them excellent candidates for the propulsion of environmentally-benign, full range (≥ 300 miles) vehicles.1 However, the actual commercialization of PEMFC powered cars has been deterred by the lack of a hydrogen infrastructure and the high cost of the PEMFC. In this last respect, a significant fraction of the system's price is related to the costly platinum-based catalysts needed to catalyze the oxidation of hydrogen and the reduction of oxygen taking place at the FC anode and cathode, respectively.1-3 The kinetics of the oxygen reduction reaction (ORR) on Pt 4 are ≈7 orders of magnitude slower than those of the hydrogen oxidation reaction (HOR), 5 in agreement with the HOR 5 -and ORR 4 -exchange-current density (i 0 ) values of 4 ± 2 · 10 +2 mA · cmPt estimated by Neyerlin and coworkers (at 80• C and 100 kPa H 2 /air partial pressure). As such, the Pt-loading at the PEMFC's cathode (≈0.2-0.4 mg Pt · cm −2 ) is well above the ≤ 0.05 mg Pt · cm −2 required for the anodic HOR, and thus much research is being devoted to the development of more active and/or less expensive ORR catalysts.6-10 These include alloys of Pt with non-noble metals like Ni, Co or Cu (as well as their de-alloyed derivatives), and catalysts consisting of non-noble metal nanoparticles covered by one or a few monolayers of Pt (i.e., the so-called "core-shell" catalysts).Alternatively, operating a fuel cell in alkaline environment allows for the use a wider variety of potentially inexpensive, noblemetal free ORR-catalysts. Among these, certain materials based on Fe-, Co-and/or Cu-N 4 chelates (or equivalent no...

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“…On the other hand, Sheng and collaborators 9 have recently estimated essentially identical HOR/HER exchange current densities of ≈0.7 mA · cm Pt −2 (at 293 K) for polycrystalline Pt and carbon-supported Pt nanoparticles of ≈2 nm diameter, which would suggest the absence of structure sensitivity for the HOR/HER, contrary to the well-known structure sensitivity of the ORR on Pt 6,12,13 and to the results of the HOR/HER studies on Pt single crystals 11,14,15 discussed above. One may speculate that this discrepancy might arise from the contamination of the Pt(hkl) surfaces with electrolyte impurities resulting from the leaching of glass components in the electrochemical cell upon contact with the alkaline solution, 16,17 which was successfully suppressed in Ref. 9 by minimizing the measurement delay.…”

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confidence: 99%

Kinetics of the Hydrogen Oxidation/Evolution Reaction on Polycrystalline Platinum in Alkaline Electrolyte Reaction Order with Respect to Hydrogen Pressure

Rheinländer

Herranz

Durst

et al. 2014

J. Electrochem. Soc.

242

236

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The hydrogen oxidation and evolution reactions (HOR, HER) are of key importance to the development of novel alkaline membrane fuel cells and electrolyzers, which feature a potential cost advantage over their acid-operating counterparts. However, their mechanism remains poorly understood even on the most catalytically-active platinum surfaces, for which such a fundamental parameter as the reactions' order with respect to the hydrogen concentration is still unknown. With this motivation, we have performed rotating disc electrode measurements on polycrystalline Pt in 0.1 M NaOH with different hydrogen partial pressures (between 10 and 100 kPa H 2 ), from which we have derived a reaction order of 1/2. The latter value has important implications in the procedure to follow in order to derive kinetic currents free of diffusion contributions. More precisely, the HOR currents must be corrected for the diffusion overpotential and converted into a mass-transport free kinetic current using a modified version of the Koutecky-Levich equation that takes into consideration this non-unit reaction order, while the HER side only needs to be ohmically compensated due to the impossibility to supersaturate the electrolye with H 2 . Most importantly, our results point at a mechanism consisting of a dissociative adsorption (Tafel) reaction combined with a one-electron transfer (Volmer) rate-determining step, in terms consistent with the well-established view of the hydrogen-bonding strength as the main HOR/HER activity descriptor. The electrochemical oxidation and evolution of molecular hydrogen are the key reactions at play in the anodes and cathodes of fuel cells and electrolyzers, respectively, which are likely energy conversion and storage devices for renewable energy concepts based on the use of H 2 as energy carrier. Beyond this practical interest, the hydrogen oxidation and evolution reactions (HOR and HER, respectively) have also played a pivotal role in the historical development of fundamental electrocatalysis theories. Indeed, the exponential relation between current and overpotential that describes the kinetics of many electrochemical reactions, viz., the Butler-Volmer equation, was originally validated for the HER, 1 which also became the first electrochemical process for which the rate-determining role of the bond strength of adsorbed intermediates (following Sabatier's principle) was verified.2 Thus, the HOR/HER has become one of the most extensively studied electrochemical reactions, particularly at low pH values and on the catalytically most active platinum-based materials relevant to proton exchange membrane fuel cells (PEMFCs) and electrolyzers. In acid electrolytes, the HOR/HER kinetics on platinum electrodes are extremely fast, so that experimental methods which afford very high mass-transport rates are required in order to unambiguously differentiate kinetic-and diffusion-overpotentials (e.g., hydrogen pump experiments in PEMFC 3 or the recently developed floating porous gas diffusion electrode method 4 ). Using t...

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Impact of Glass Corrosion on the Electrocatalysis on Pt Electrodes in Alkaline Electrolyte

Cited by 148 publications

References 30 publications

On the oxygen reduction reaction in phosphoric acid electrolyte: Evidence of significantly increased inhibition at steady state conditions

On the oxygen reduction reaction in phosphoric acid electrolyte: Evidence of significantly increased inhibition at steady state conditions

Bulk-Palladium and Palladium-on-Gold Electrocatalysts for the Oxidation of Hydrogen in Alkaline Electrolyte

Kinetics of the Hydrogen Oxidation/Evolution Reaction on Polycrystalline Platinum in Alkaline Electrolyte Reaction Order with Respect to Hydrogen Pressure

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