La and Ca-Doped A-Site Deficient Strontium Titanates Anode for Electrolyte Supported Direct Methane Solid Oxide Fuel Cell

Tiwari, Pankaj; Yue, Xiangling; Irvine, John T. S.; Basu, Suddhasatwa

doi:10.1149/2.0201712jes

Cited by 18 publications

(18 citation statements)

References 30 publications

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“…[111,[126][127][128][129] With impregnated ceria (6-10 wt%) and Ni (3-5 wt%), a dramatic enhancement in anode performance was obtained compared to that of the bare LSCT A− backbone and the backbone with ceria only. [111,[126][127][128][129] With impregnated ceria (6-10 wt%) and Ni (3-5 wt%), a dramatic enhancement in anode performance was obtained compared to that of the bare LSCT A− backbone and the backbone with ceria only.…”

Section: Perovskite Lst Based Scaffoldmentioning

confidence: 99%

“…Irvine et al. have carried out extensive studies on infiltration into the A‐site deficient La 0.2 Sr 0.25 Ca 0.45 TiO 3 (LSCT A− ) anode SOFC, testing with H 2 as well as CH 4 . With impregnated ceria (6–10 wt%) and Ni (3–5 wt%), a dramatic enhancement in anode performance was obtained compared to that of the bare LSCT A− backbone and the backbone with ceria only .…”

Section: Impregnated Anodesmentioning

confidence: 99%

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Tailoring SOFC Electrode Microstructures for Improved Performance

Connor

Yue

Savaniu

et al. 2018

Advanced Energy Materials

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203

108

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The key technical challenges that fuel cell developers need to address are performance, durability, and cost. All three need to be achieved in parallel; however, there are often competitive tensions, e.g., performance is achieved at the expense of durability. Stability and resistance to degradation under prolonged operation are key parameters. There is considerable interest in developing new cathodes that are better able to function at lower temperature to facilitate low cost manufacture. For anodes, the ability of the solid oxide fuel cell (SOFC) to better utilize commonly available fuels at high efficiency, avoid coking and sulfur poisoning or resistance to oxidation at high utilization are all key. Optimizing a new electrode material requires considerable process development. The use of solution techniques to impregnate an already optimized electrode skeleton, offers a fast and efficient way to evaluate new electrode materials. It can also offer low cost routes to manufacture novel structures and to fine tune already known structures. Here impregnation methodologies are discussed, spectral and surface characterization are considered, and the recent efforts to optimize both cathode and anode functionalities are reviewed. Finally recent exemplifications are reviewed and future challenges and opportunities for the impregnation approach in SOFCs are explored.

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Section: Perovskite Lst Based Scaffoldmentioning

confidence: 99%

Section: Impregnated Anodesmentioning

confidence: 99%

Tailoring SOFC Electrode Microstructures for Improved Performance

Connor

Yue

Savaniu

et al. 2018

Advanced Energy Materials

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203

108

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“…For this purpose, the first step is to improve the anode of SOFC which is not only catalytically active for breaking the C―H bond with subsequent release of syngas, but also be electron conductive. In recent years, oxygen‐deficient and mixed‐valent perovskite materials have been shown to have a potential application as SOFC anode materials because of their appropriate catalytic activity and electro‐conductivity. For example, molybdenum‐based double perovskites Sr 2 MMoO 6‐δ (M = Co, Ni, Fe, Mn, and Mg) have exhibited excellent catalytic activity towards the electro‐oxidation of H 2 and CH 4 .…”

Section: Introductionmentioning

confidence: 99%

Enhanced coking resistance of Ni cermet anodes for solid oxide fuel cells based on methane on‐cell reforming by a redox‐stable double‐perovskite Sr ₂ MoFeO _6‐δ

et al. 2018

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Summary Carbon deposition on a Ni‐based anode is troublesome for the direct power generation from methane‐based fuels using solid oxide fuel cell. In this paper, a redox‐stable double‐perovskite Sr2MoFeO6‐δ (SMFO) is applied as an independent on‐cell reforming catalyst over a Ni‐YSZ anode to improve coking resistance. The morphology, catalytic activity and electrochemical performance for wet methane/coal‐bed gas (CBG) are investigated. A Ni‐YSZ anode supported cell with SMFO generates a high power output of 1.77 W·cm−2 and exhibits favorable stability operated on wet CH4 at 800°C. Post‐mortem micro‐structural analyses of cells indicate the cell operated on CBG shows coking probably due to the heavy carbon compounds in CBG.

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“…Though the electrocatalytic activity of LSCT A− toward direct methane oxidation was low, it did not promote coking during this operational period. [55] Addition of 6 wt% CeO 2 appeared to improve performance, giving a maximum power density of 194 mW cm −2 in a H 2 fuel gas. However, despite the fact that coimpregnation of 6 wt% CeO 2 and 4 wt% Ni (similar to the catalyst system employed by Verbraeken et al) gave an improved maximum power density of 328 mW cm −2 in the same fuel, upon switching to "dry" methane, a maximum power density of only 250 mW cm −2 was achieved, which rapidly degraded to 165 mW cm −2 after only 3 h, implying the Ni catalyst phase was encouraging coke formation.…”

Section: Testing Of Impregnated Lsct A− Anodes Under Differing Operatmentioning

confidence: 99%

“…However, despite the fact that coimpregnation of 6 wt% CeO 2 and 4 wt% Ni (similar to the catalyst system employed by Verbraeken et al) gave an improved maximum power density of 328 mW cm −2 in the same fuel, upon switching to "dry" methane, a maximum power density of only 250 mW cm −2 was achieved, which rapidly degraded to 165 mW cm −2 after only 3 h, implying the Ni catalyst phase was encouraging coke formation. [55] Although operation in "dry" methane is not relevant to the system requirements of HEXIS, [3][4][5] this research provided an indicator that alternative catalysts to Ni may need to be sought in order to reduce or prevent coking and/or sulfur poisoning in unprocessed natural gas feeds for next-generation anodes.…”

Section: Testing Of Impregnated Lsct A− Anodes Under Differing Operatmentioning

confidence: 99%

Upscaling of Co‐Impregnated La_0.20Sr_0.25Ca_0.45TiO₃ Anodes for Solid Oxide Fuel Cells: A Progress Report on a Decade of Academic‐Industrial Collaboration

Price

Cassidy

Grolig

et al. 2021

Advanced Energy Materials

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and useful electrical power from a fuel gas (e.g., natural gas), at much higher conversion efficiencies than conventional combustion methods. [1,2] This method of heat and electricity co-generation makes SOFC technology ideal for use in micro-combined heat and power (µ-CHP) units, particularly in the 1-5 kW (electrical power) output class, which may be used to satisfy the total heat and electricity demand of family homes and small businesses. An example of such a unit is the Galileo 1000 N, produced by HEXIS AG between 2013 and 2018. [3] This µ-CHP unit was successfully commercialized with more than 100 units being installed in a variety of locations across Western Europe, each providing 1 kW of electrical power and 20 kW of heat (from an auxiliary burner). [4,5] Currently, the Swiss SOFC manufacturer is focusing on the development of the next-generation SOFC-based µ-CHP unit, designed to provide an increased electrical power output of 1.5 kW at a higher electrical efficiency. [3,6] Typically, high-temperature SOFC (operating at 700-850 °C) are produced using traditional, well-studied, and effective material sets, which have been tailored to suit the requirements of each component. For example, air electrodes (cathodes) are often made from composites of yttria-stabilized zirconia (YSZ) and strontium-substituted lanthanum manganite (LSM) [7][8][9] or composites of cerium gadolinium oxide (CGO) and strontium-substituted lanthanum cobaltite (LSC), [9,10] ferrite (LSF), [11] or cobaltite ferrite (LSCF). [8,[12][13][14][15][16] Electrolytes used in SOFC operating within this temperature regime are zirconia stabilized, commonly, with scandia or yttria (ScSZ or YSZ), [2] while fuel electrodes (anodes) traditionally comprise composites of Ni and either YSZ or CGO. [2,17] However, despite the excellent performance that can be obtained using these materials, there are several challenges posed, specifically, by the anode materials, that must be addressed in order to provide greater resistance to harsh operating conditions in next-generation SOFC systems. These ceramic-metal composites (cermets) of YSZ/CGO and Ni exhibit redox instability, due to the propensity of Ni to agglomerate, in addition to sulfur poisoning and carbon deposition during exposure to unprocessed natural gas feeds. [1,18] Several different materials design approaches have been identified and explored in an attempt to mitigate the limitations of the Solid oxide fuel cell (SOFC) stack technology offers a reliable, efficient, and clean method of sustainable heat and electricity co-generation that can be integrated into micro-combined heat and power (µ-CHP) units for use in residential and small commercial environments. Recent years have seen the successful market introduction of several SOFC-based systems, however, manufacturers still face some challenges in improving the durability and tolerance of traditional Ni-based ceramic-metal (cermet) composite anodes to harsh operating conditions, such as redox and thermal cycling, overload exposure, sulfur poisonin...

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La and Ca-Doped A-Site Deficient Strontium Titanates Anode for Electrolyte Supported Direct Methane Solid Oxide Fuel Cell

Cited by 18 publications

References 30 publications

Tailoring SOFC Electrode Microstructures for Improved Performance

Tailoring SOFC Electrode Microstructures for Improved Performance

Enhanced coking resistance of Ni cermet anodes for solid oxide fuel cells based on methane on‐cell reforming by a redox‐stable double‐perovskite Sr ₂ MoFeO _6‐δ

Upscaling of Co‐Impregnated La_0.20Sr_0.25Ca_0.45TiO₃ Anodes for Solid Oxide Fuel Cells: A Progress Report on a Decade of Academic‐Industrial Collaboration

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La and Ca-Doped A-Site Deficient Strontium Titanates Anode for Electrolyte Supported Direct Methane Solid Oxide Fuel Cell

Cited by 18 publications

References 30 publications

Tailoring SOFC Electrode Microstructures for Improved Performance

Tailoring SOFC Electrode Microstructures for Improved Performance

Enhanced coking resistance of Ni cermet anodes for solid oxide fuel cells based on methane on‐cell reforming by a redox‐stable double‐perovskite Sr 2 MoFeO 6‐δ

Upscaling of Co‐Impregnated La0.20Sr0.25Ca0.45TiO3 Anodes for Solid Oxide Fuel Cells: A Progress Report on a Decade of Academic‐Industrial Collaboration

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Enhanced coking resistance of Ni cermet anodes for solid oxide fuel cells based on methane on‐cell reforming by a redox‐stable double‐perovskite Sr ₂ MoFeO _6‐δ

Upscaling of Co‐Impregnated La_0.20Sr_0.25Ca_0.45TiO₃ Anodes for Solid Oxide Fuel Cells: A Progress Report on a Decade of Academic‐Industrial Collaboration