Insight into the Reaction Mechanism of (La0.58Sr0.40)(Co0.20Fe0.80)O3-δCathode with Volatile Chromium Species at High Current Density in a Solid Oxide Fuel Cell Stack

Beez, Alexander; Yin, Xu-Cheng; Menzler, Norbert H.; Spatschek, Robert; Bram, Martin

doi:10.1149/2.0051710jes

Cited by 31 publications

(33 citation statements)

References 47 publications

(76 reference statements)

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“…As stated previously, chemical analysis showed that chromium can also be found in higher amounts at the air inlet than at the air outlet. This phenomenon has been shown before: strontium chromate is more likely to form at the air inlet than at the air outlet (25). Additionally, LSCF is obviously not stable over 18 000 hours in electrolysis mode and strontium diffuses into the electrolyte as well as to the top of the cell.…”

Section: Investigation Of Layer 2 -Effects Of the Burningmentioning

confidence: 77%

A Detailed Post Mortem Analysis of Solid Oxide Electrolyzer Cells after Long-Term Stack Operation

Frey

Sebold

Menzler

et al. 2018

J. Electrochem. Soc.

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A long-term test with a two-layer solid oxide electrolyzer stack was carried out for more than 20 000 hours. The stack was mainly operated in a furnace environment in electrolysis mode, with 50% humidification of H2 at 800 °C, a current density of -0.5 Acm -2 and steam conversion rate of 50%. After ~18 000 hours of operation in electrolysis mode, the voltage and area specific resistance degradation rates were ~0.6%/kh and 8.2%/kh, respectively. A detailed post mortem analysis of cells including ICP-OES and microstructural analysis was conducted. Two main degradation phenomena were observed in the cells: In the fuel electrode, the depletion and agglomeration of nickel were visible. At the air electrode, demixing of the air electrode and diffusion of strontium took place. This was observed in the formation of strontium zirconate at the interface between the electrolyte and the GDC barrier layer as well as in the formation of strontium oxide and strontium chromate on top of the cells. Strontium oxide was even found in pores on top of the electrolyte.

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Section: Investigation Of Layer 2 -Effects Of the Burningmentioning

confidence: 77%

A Detailed Post Mortem Analysis of Solid Oxide Electrolyzer Cells after Long-Term Stack Operation

Frey

Sebold

Menzler

et al. 2018

J. Electrochem. Soc.

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“…We applied this diagram to explain Cr species deposition under real stack operation conditions. More detailed information can be found in the co‐work with A. Beez …”

Section: Thermodynamic Aspects Of Cr Poisoningmentioning

confidence: 99%

Thermodynamic perspective of Sr‐related degradation issues in SOFCs

Yin

Bencze²,

Моталов

et al. 2017

Int J Applied Ceramic Tech

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La,Sr)(Co,Fe)O 3-d is very common as cathode material in SOFC applications. Sr in this type of cathode material is very reactive to form secondary phases with other oxides, which affect micro-structures and properties of the cathode materials, GDC layers and ZrO 2 -based electrolytes. The Sr-related degradation issues, Cr poisoning and volatile Sr species formation, are studied. As supplement to existing experimental knowledge on Cr poisoning, specific thermodynamic aspects for Cr poisoning are discussed. The thermodynamic calculations show that the partial pressure pCrO 3 has a stronger temperature dependence than pCrO 2 (OH) 2 , and when considering the reaction between SrO and CrO 3 (g), dependent on different pCrO 3 and pO 2 , different Sr-Cr-O compounds SrCrO 4 , SrCrO 3 , Sr 3 Cr 2 O 8 or Sr 2 CrO 4 could be formed. In addition, thermodynamic calculations show that in the presence of water vapor, formation of volatile Sr(OH) 2 is possible as well. pSr(OH) 2 depends on temperature, pH 2 O and SrO activity and can be of the same order of magnitude as pCrO 2 (OH) 2 . Volatile Sr(OH) 2 can diffuse through the porous GDC layer and react with ZrO 2 -based electrolytes to form SrZrO 3 precipitates. The reaction between gaseous Sr species and 8YSZ sheet is studied experimentally. The surface of the 8YSZ sheet is investigated by SEM coupled with EDS, confirming the deposition of Sr. K E Y W O R D S degradation, solid oxide fuel cell, thermodynamics

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Section: Discussionmentioning

confidence: 99%

“…The amount of Cr deposited on the cathode strongly depends on the Cr protection coating applied to the interconnect and the operating temperature (Beez et al, 2017). For stacks with less efficient Cr protection coatings (e.g., porous coatings applied by wet powder spraying), which were operated for up to 17.000 h, we measured a Cr content in the range of 100-200 µg cm −2 on the stack level (Menzler et al, 2011;Menzler and Batfalsky, 2012;Beez et al, 2017). So far a non-linear correlation between the amount of Cr deposited on an LSCF cathode and the operation time of a stack was measured (Menzler and Batfalsky, 2012) and a Cr content in the range of 200 µg cm −2 is the highest value reached for JÜLICH ASC stacks so far.…”

Section: Discussionmentioning

confidence: 99%

“…The amount of Cr 2 O 3 powder in the paste was calculated considering the wet layer thickness of the screen used for the screen printing process. It was targeted to achieve a Cr deposition, which is comparable to average Cr contents found in LSCF cathodes after several thousand hours of stack operation with JÜLICH specific stack design (∼100-200 µg cm −2 ) (Menzler et al, 2011;Beez et al, 2017). The Cr content of the paste was adjusted to 6.2 wt.-% (equals 0.1 g Cr 2 O 3 per 1 g organic matrix) with the aim to achieve a Cr deposition of ∼100 µg cm −2 .…”

Section: Experimental Paste Preparationmentioning

confidence: 99%

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Accelerated Testing of Chromium Poisoning of Sr-Containing Mixed Conducting Solid Oxide Cell Air Electrodes

et al. 2018

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A straightforward method for accelerated testing of Cr poisoning phenomena on mixed ionic and electronic conducting (MIEC) Solid Oxide Cell (SOC) air electrode materials was developed. Cr 2 O 3 -powder is mixed with an organic matrix and screen printed onto anode-supported button cells with (La,Sr)(Co,Fe)O 3−δ (LSCF) cathode. Then, a thermal treatment was conducted to achieve the formation of a well-defined amount of SrCrO 4 on the cathode surface within only a few hours. For the proof of concept, single cell measurements were done to investigate the influence of this new kind of Cr deposition. As reference, a cell poisoned via gas phase diffusion and a cell without any Cr contamination were characterized in the same manner. According to the impedance data, the polarization resistance for both cells, which were contaminated with Cr species, increased. The expected relationship between deposited amount of Cr and increase of polarization resistance was found. ICP-OES analysis proves the high reproducibility of the method as the Cr content is only a function of the Cr paste composition and almost independent of external poisoning conditions. Due to its scalability and reproducibility, this method is proposed to be a new tool for screening of cathode materials and the investigation of different stages of Cr poisoning prior to more sophisticated and time consuming investigations like stack tests.

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Insight into the Reaction Mechanism of (La_0.58Sr_0.40)(Co_0.20Fe_0.80)O_3-δCathode with Volatile Chromium Species at High Current Density in a Solid Oxide Fuel Cell Stack

Cited by 31 publications

References 47 publications

A Detailed Post Mortem Analysis of Solid Oxide Electrolyzer Cells after Long-Term Stack Operation

A Detailed Post Mortem Analysis of Solid Oxide Electrolyzer Cells after Long-Term Stack Operation

Thermodynamic perspective of Sr‐related degradation issues in SOFCs

Accelerated Testing of Chromium Poisoning of Sr-Containing Mixed Conducting Solid Oxide Cell Air Electrodes

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