Influence of SO<sub>2</sub> on the Long-Term Durability of SOFC Cathodes

Liu, Run-Ru; Taniguchi, Shunsuke; Shiratori, Yusuke; Ito, Kohei; Sasaki, Kazunari

doi:10.1149/1.3570221

Cited by 30 publications

(20 citation statements)

References 45 publications

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“…These perovskites easily form carbonates and sulphates (mainly Ba and Sr carbonates/sulphates) or undergo phase segregation [13,16]. This was also observed in several works focused on La0.6Sr0.4Co0.2Fe0.8O3-δ stability when used as SOFC cathodes exposed to CO2 and SO2 [28][29][30], as well as for similar perovskites consisting of La0.6Sr0.4CoO3-δ [31,32]. In addition, the presence of steam in the system affects both the oxygen transport properties and the thermochemical resistance of MIECs [15,[33][34][35].…”

Section: So2supporting

confidence: 61%

Thermochemical stability of LaxSr1-xCoyFe1-yO3-δ and NiFe2O4-Ce0.8Tb0.2O2-δ under real conditions for its application in oxygen transport membranes for oxyfuel combustion

Bermúdez

García‐Fayos

Reina

et al. 2018

Journal of Membrane Science

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Section: So2supporting

confidence: 61%

Thermochemical stability of LaxSr1-xCoyFe1-yO3-δ and NiFe2O4-Ce0.8Tb0.2O2-δ under real conditions for its application in oxygen transport membranes for oxyfuel combustion

Bermúdez

García‐Fayos

Reina

et al. 2018

Journal of Membrane Science

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“…Various volatile impurities exist in SOC stacks, such as gaseous CrO 3 from chromia-forming metallic interconnects and high-temperature alloys used in Balance-of-Plant (BoP) components, SO 2 , CO 2 and H 2 O from airstream and boron species from borosilicate glass sealants. Surface-segregated cations tend to interact actively with these volatile impurities, leading to the deposition of impurities, microstructural changes and operating instability [39,48,49,57,[187][188][189][190][191][192][193][194][195][196][197][198][199][200][201][202][203].…”

Section: Reactivity Of Segregated Cation Species With Volatile Impuritiesmentioning

confidence: 99%

“…Sulphur in air streams can significantly affect the performance and durability of SOFCs [191,215,216]. For example, Wang et al [217] studied the mechanism and kinetics of sulphur deposition on LSM electrodes at 700 °C and 800 °C in 1 ppm and 10 ppm SO 2 and reported that the deposition of SO Xiong et al [191] also investigated the sulphur poisoning of LSM electrodes in highly concentrated 0.01% SO 2 in air and reported that the LSM electrode was relatively stable during cathodic polarization at 800 °C for 5 h. On the other hand, Liu et al [190] tested a double-layer oxygen electrode with an LSM-ScSZ inner layer and an LSM outer layer in 20 ppm SO 2 and reported that after cathodic polarization at 800 °C for 1000 h, SrSO 4 particles were observed around the LSM particles in both layers of the electrode. Wang et al [218] further reported that the deposition of sulphur and formation of SrSO 4 were at the LSM/YSZ interface in the presence of 1 ppm SO 2 at 800 °C under anodic polarization conditions and attributed this to the fact that anodic polarization can promote SrO segregation at the LSM close to the YSZ electrolyte, promoting the formation of SrSO 4 and interfacial delamination.…”

Section: Somentioning

confidence: 99%

“…Compared with LSM, cobaltite oxygen electrodes such as LSC, Sm 0.5 Sr 0.5 CoO 3 (SSC) and LSCF have much higher tendencies to react with SO 2 . For example, Schuler et al [58,219] exposed a double-layer oxygen electrode consisting of a LSM-YSZ inner layer and an LSC outer layer to ~ 12 ppb SO 2 and reported that after operation at 800 °C for 1900 h, SrSO 4 preferentially deposited onto the LSC layer, in which the formation of more SrSO 4 on the cobaltite electrodes as compared with that on LSM electrodes was believed to be due to the higher activity of SrO in cobaltite electrodes [58,190,191]. Here, the reaction between SO 2 and LSC is favourable under oxygen-rich atmospheres and can be described by:…”

Section: Somentioning

confidence: 99%

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Surface Segregation in Solid Oxide Cell Oxygen Electrodes: Phenomena, Mitigation Strategies and Electrochemical Properties

Chen

Jiang

2020

Electrochem. Energ. Rev.

117

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Solid oxide cells (SOCs) are highly efficient and environmentally benign devices that can be used to store renewable electrical energy in the form of fuels such as hydrogen in the solid oxide electrolysis cell mode and regenerate electrical power using stored fuels in the solid oxide fuel cell mode. Despite this, insufficient long-term durability over 5–10 years in terms of lifespan remains a critical issue in the development of reliable SOC technologies in which the surface segregation of cations, particularly strontium (Sr) on oxygen electrodes, plays a critical role in the surface chemistry of oxygen electrodes and is integral to the overall performance and durability of SOCs. Due to this, this review will provide a critical overview of the surface segregation phenomenon, including influential factors, driving forces, reactivity with volatile impurities such as chromium, boron, sulphur and carbon dioxide, interactions at electrode/electrolyte interfaces and influences on the electrochemical performance and stability of SOCs with an emphasis on Sr segregation in widely investigated (La,Sr)MnO3 and (La,Sr)(Co,Fe)O3−δ. In addition, this review will present strategies for the mitigation of Sr surface segregation. Graphic Abstract

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“…45 The results are in good accordance with the previous experimental results, i.e., the sulfur poisoning deactivates the active cathode and causes deterioration in the microstructure. 9,10,13,20 It also offers a deep understanding of SO 2 poisoning of the LSM cathode and helps to optimize the material composition and morphology to avoid potential mechanical failure and catalytic deactivation.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Analysis of Thermal Stress in a Solid Oxide Fuel Cell Due to the Sulfur Poisoning Interface of the Electrolyte and Cathode

Zhang

et al. 2021

Energy Fuels

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The interface of an electrolyte and cathode strongly determines the oxygen reduction reaction and cell stability, but it is susceptible to sulfur impurities like SO2 in air. In this study, a 3D solid oxide fuel cell model is developed based on experimental characterization to reveal sulfur-deactivating active cathodes. The results indicate that both the average values for electric and ionic current densities drastically decrease after sulfur poisoning; meanwhile, their distributions are also changed, suggesting that the involved oxygen reduction reaction is detrimentally affected. Moreover, the temperature decreases after poisoning due to electrochemical reaction slowdown near the interface of the active cathode and electrolyte. The pronounced temperature changes together with differences in the thermal expansion coefficient of neighboring components, further resulting in uneven stress distributions at the active cathode, possibly bringing out cracks and bending. Thermal stresses are reduced after sulfur poisoning, especially for the third principal stress, which produces a decrement of 154 MPa. The visualized results of the current density, temperature, and stresses are helpful to understand the sulfur poisoning behavior and also to better understand the internal changes of some crucial electrochemical processes beneficial for further optimization of the microstructural stability.

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Influence of SO₂ on the Long-Term Durability of SOFC Cathodes

Cited by 30 publications

References 45 publications

Thermochemical stability of LaxSr1-xCoyFe1-yO3-δ and NiFe2O4-Ce0.8Tb0.2O2-δ under real conditions for its application in oxygen transport membranes for oxyfuel combustion

Thermochemical stability of LaxSr1-xCoyFe1-yO3-δ and NiFe2O4-Ce0.8Tb0.2O2-δ under real conditions for its application in oxygen transport membranes for oxyfuel combustion

Surface Segregation in Solid Oxide Cell Oxygen Electrodes: Phenomena, Mitigation Strategies and Electrochemical Properties

Analysis of Thermal Stress in a Solid Oxide Fuel Cell Due to the Sulfur Poisoning Interface of the Electrolyte and Cathode

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Influence of SO2 on the Long-Term Durability of SOFC Cathodes

Cited by 30 publications

References 45 publications

Thermochemical stability of LaxSr1-xCoyFe1-yO3-δ and NiFe2O4-Ce0.8Tb0.2O2-δ under real conditions for its application in oxygen transport membranes for oxyfuel combustion

Thermochemical stability of LaxSr1-xCoyFe1-yO3-δ and NiFe2O4-Ce0.8Tb0.2O2-δ under real conditions for its application in oxygen transport membranes for oxyfuel combustion

Surface Segregation in Solid Oxide Cell Oxygen Electrodes: Phenomena, Mitigation Strategies and Electrochemical Properties

Analysis of Thermal Stress in a Solid Oxide Fuel Cell Due to the Sulfur Poisoning Interface of the Electrolyte and Cathode

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Influence of SO₂ on the Long-Term Durability of SOFC Cathodes