Solid Oxide Fuel Cell Anode Materials for Direct Hydrocarbon Utilization

Ge, Xiaoming; Chan, Siew Hwa; Liu, Qinglin; Sun, Qiang

doi:10.1002/aenm.201200342

Cited by 278 publications

(175 citation statements)

References 395 publications

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“…Also, the considered nonhydrogen fuels usually contain sulfur (in a form of H 2 S), which can irreversibly poison Ni-YSZ cermet anodes. [1][2][3] It may be stated that construction of robust SOFCs with fuel versatility relies upon a development of the anode materials with improved tolerance towards carbon deposition and sulfur poisoning. Mo-containing perovskitetype oxides have shown promise in this respect.…”

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confidence: 99%

“…In the case of well-established Ni-YSZ cermet anode, the performance degradation upon coking arises mainly from a decrease in length of the Triple Phase Boundary (TPB) on the anode, which limits the number of catalytic sites needed for fuel oxidation. 1,2 Furthermore, the deposited carbon may expand and destroy mechanical integrity of the electrode. Also, the considered nonhydrogen fuels usually contain sulfur (in a form of H 2 S), which can irreversibly poison Ni-YSZ cermet anodes.…”

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confidence: 99%

“…Versatile fuel utilization can be an essential factor for future development and commercial adoption of SOFC technology in power generation, for instance, from biogas used as a renewable energy source. 1,2 One of the main challenges with SOFCs running directly on carbon containing fuels, such as syngas, methane/biogas or other hydrocarbons, is carbon deposition occurring on the anode, which results in a significant, and sometimes detrimental decrease of the performance. In the case of well-established Ni-YSZ cermet anode, the performance degradation upon coking arises mainly from a decrease in length of the Triple Phase Boundary (TPB) on the anode, which limits the number of catalytic sites needed for fuel oxidation.…”

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Carbon Deposition and Sulfur Poisoning in SrFe_0.75Mo_0.25O_3-δand SrFe_0.5Mn_0.25Mo_0.25O_3-δElectrode Materials for Symmetrical SOFCs

Zheng

Świerczek

Polfus

et al. 2015

J. Electrochem. Soc.

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Redox stable SrFe 0.75 Mo 0.25 O 3-δ and SrFe 0.5 Mn 0.25 Mo 0.25 O 3-δ electrode materials were studied in terms of their physicochemical properties and electrochemical performance in symmetrical SOFCs, with focus on their tolerance toward carbon deposition and sulfur poisoning. Both materials possess cubic, B-site cation-disordered Pm-3m structure in air up to high temperatures. SrFe 0.5 Mn 0.25 Mo 0.25 O 3-δ was found to transform to a B-site cation-ordered structure after reduction in dry 5 vol% H 2 /Ar at 1100 • C, while no structural changes were observed for SrFe 0.75 Mo 0.25 O 3-δ . Weight change upon annealing up to 850 • C in air and in dry 5 vol% H 2 /Ar indicated an increase in oxygen deficiency on the order of δ = 0.2. Seebeck coefficient and conductivity dependence on the oxygen partial pressure pO 2 showed that both oxides exhibit p-type conductivity in air and n-type conductivity under reducing conditions. Carbon deposition was found to depend on temperature, gas composition (CO or CH 4 ), and presence of Ce 0.8 Gd 0.2 O 1.9 electrolyte in the composite-type electrode. Stable fuel cell performance, without carbon deposition, was obtained for SrFe 0.75 Mo 0.25 O 3-δ -based SOFC in 10 vol% of CO in CO 2 . Also, SOFC operation with CH 4 as fuel was achieved without coking at temperatures ≤ 700 • C. However, both oxides suffer from sulfur poisoning-related effects in atmosphere with 800 ppm H 2 S. Compatibility of Solid Oxide Fuel Cells (SOFCs) with nonhydrogen fuels represents their important advantage over other types of fuel cells. Versatile fuel utilization can be an essential factor for future development and commercial adoption of SOFC technology in power generation, for instance, from biogas used as a renewable energy source.1,2 One of the main challenges with SOFCs running directly on carbon containing fuels, such as syngas, methane/biogas or other hydrocarbons, is carbon deposition occurring on the anode, which results in a significant, and sometimes detrimental decrease of the performance. In the case of well-established Ni-YSZ cermet anode, the performance degradation upon coking arises mainly from a decrease in length of the Triple Phase Boundary (TPB) on the anode, which limits the number of catalytic sites needed for fuel oxidation.1,2 Furthermore, the deposited carbon may expand and destroy mechanical integrity of the electrode. Also, the considered nonhydrogen fuels usually contain sulfur (in a form of H 2 S), which can irreversibly poison Ni-YSZ cermet anodes.1-3 It may be stated that construction of robust SOFCs with fuel versatility relies upon a development of the anode materials with improved tolerance towards carbon deposition and sulfur poisoning. Mo-containing perovskitetype oxides have shown promise in this respect.3,4 The considered family of materials possesses crystal structure that can be either B-site cation disordered, denoted as AM 1-x Mo x O 3-δ (A: Sr, Ba; M: 3d metals) or B-site cation-ordered one (so called double perovskite structure), A 2 M 2-x Mo x O 6-δ . 3,5 T...

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Carbon Deposition and Sulfur Poisoning in SrFe_0.75Mo_0.25O_3-δand SrFe_0.5Mn_0.25Mo_0.25O_3-δElectrode Materials for Symmetrical SOFCs

Zheng

Świerczek

Polfus

et al. 2015

J. Electrochem. Soc.

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“…Carbon deposition on the Ni-based anode when hydrocarbon fuels are used in the SOFCs is a challenge [1,2]. Therefore, it is desired to develop new anode, particularly redox stable anode for SOFCs [3][4][5][6][7][8][9][10]. Double perovskite Sr 2 (TM)MoO 6-d (TM = Mn, Mg, Fe, Co, Ni, Cu, Zn) as potential anode materials for SOFCs has been the subject of a substantial body of research [3,5,8,9,11], and good fuel cell performance has been achieved for Sr 2 MgMoO 6-d [5], Sr 2 MnMoO 6-d [5], Sr 2 CoMoO 6-d [12] and Sr 2 FeMoO 6-d [13] anodes; of these compounds, only Sr 2 MgMoO 6-d (SMMO) has been proven to be redox stable [14].…”

Section: Introductionmentioning

confidence: 99%

Conductivity and redox stability of new double perovskite oxide Sr1.6K0.4Fe1+x Mo1−x O6−δ (x = 0.2, 0.4, 0.6)

et al. 2016

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“…With up to 60% energy efficiency and a life expectancy of 40,000 hours, the SOFC has emerged as an ideal candidate to meet the energy challenges of the modern world. [1][2][3] However, the commercialization of SOFC is hindered due to its high operating temperature, manufacturing cost, and structural instability. [4][5][6] Structural evolution of SOFC often leads to the structural failure and shortening of SOFC lifetime.…”

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Meso-Scale Phase-Field Modeling of Microstructural Evolution in Solid Oxide Fuel Cells

Abdullah

Liu

2016

J. Electrochem. Soc.

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Microstructural evolution occurs in solid oxide fuel cells (SOFCs) during operation, which cause severe electrochemical performance degradation as well as structural failure such as crack formation. Nickel (Ni) particle coarsening is believed to cause microstructural evolution in the Ni-based anode of SOFCs. Furthermore, the accumulation of expanded pores during the microstructural evolution is responsible for crack formation. Based on the diffuse-interface theory and the phase-field method, integrating both Cahn-Hilliard equation and Ginzburg-Landau equation, a meso-scale phase-field model was established to investigate microstructural evolution and crack formation in the Ni / Yttria Stabilized Zirconia (YSZ) anode of SOFCs. Then, the model was applied to explore the coupling effects of microstructural evolution on SOFCs performance degradation. Simulation results show that particle size, porosity, and particle size ratio of Ni-YSZ are most influential parameters in microstructural evolution. It was found that the triple phase boundaries (TPBs) area was decreased by 24% and power density was decreased by 11.03% after 1000 hours of operation. In addition, the power density was decreased by 27%. This work is expected to provide us a comprehensive understanding of SOFCs' microstructural evolution as well as a tool for SOFC's performance degradation analysis. Solid oxide fuel cells (SOFCs) could be one possible solution to the depleting energy resources of the modern world due to its fuel flexibility, low carbon emissions, and high efficiency. With up to 60% energy efficiency and a life expectancy of 40,000 hours, the SOFC has emerged as an ideal candidate to meet the energy challenges of the modern world.1-3 However, the commercialization of SOFC is hindered due to its high operating temperature, manufacturing cost, and structural instability.4-6 Structural evolution of SOFC often leads to the structural failure and shortening of SOFC lifetime. 7,8 Moreover, structural evolution results in compromising SOFCs' electrochemical performance, mostly in the electrodes.A SOFC consists of both electrodes (i.e., anode and cathode) and a ceramic electrolyte. The anode is consisted of ion conducting phase and electron conducting phase to facilitate the fuel oxidation reaction. 9The cathode reduces the oxygen into oxygen ion, which is then diffused to anode through the ceramic electrolyte, such as yttria stabilized zirconia (YSZ).10 Electrochemical reaction of SOFC mainly occurs in the triple phase boundary (TPB) area, 11 where the pore phase, the ion conducting phase, and electron conducting phase join to convert chemical energy of fuel gases to electrical energy. 1,8,12,13 TPB area is the key microstructural property controlling the electrochemical activities of SOFC.14 It is desired to have a stable microstructure with optimized TPB area. 15,16 However, recent studies reveal that TPB area is often diminished due to microstructure evolution. 10,[17][18][19][20] The microstructure evolution is controlled by the Ni particle c...

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Solid Oxide Fuel Cell Anode Materials for Direct Hydrocarbon Utilization

Cited by 278 publications

References 395 publications

Carbon Deposition and Sulfur Poisoning in SrFe_0.75Mo_0.25O_3-δand SrFe_0.5Mn_0.25Mo_0.25O_3-δElectrode Materials for Symmetrical SOFCs

Carbon Deposition and Sulfur Poisoning in SrFe_0.75Mo_0.25O_3-δand SrFe_0.5Mn_0.25Mo_0.25O_3-δElectrode Materials for Symmetrical SOFCs

Conductivity and redox stability of new double perovskite oxide Sr1.6K0.4Fe1+x Mo1−x O6−δ (x = 0.2, 0.4, 0.6)

Meso-Scale Phase-Field Modeling of Microstructural Evolution in Solid Oxide Fuel Cells

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Solid Oxide Fuel Cell Anode Materials for Direct Hydrocarbon Utilization

Cited by 278 publications

References 395 publications

Carbon Deposition and Sulfur Poisoning in SrFe0.75Mo0.25O3-δand SrFe0.5Mn0.25Mo0.25O3-δElectrode Materials for Symmetrical SOFCs

Carbon Deposition and Sulfur Poisoning in SrFe0.75Mo0.25O3-δand SrFe0.5Mn0.25Mo0.25O3-δElectrode Materials for Symmetrical SOFCs

Conductivity and redox stability of new double perovskite oxide Sr1.6K0.4Fe1+x Mo1−x O6−δ (x = 0.2, 0.4, 0.6)

Meso-Scale Phase-Field Modeling of Microstructural Evolution in Solid Oxide Fuel Cells

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Carbon Deposition and Sulfur Poisoning in SrFe_0.75Mo_0.25O_3-δand SrFe_0.5Mn_0.25Mo_0.25O_3-δElectrode Materials for Symmetrical SOFCs

Carbon Deposition and Sulfur Poisoning in SrFe_0.75Mo_0.25O_3-δand SrFe_0.5Mn_0.25Mo_0.25O_3-δElectrode Materials for Symmetrical SOFCs