Investigation of Cathode Catalysts for Intermediate-temperature H2S-Air Fuel Cells

Abstract

Abstract:

Cathode catalysts comprising composite NiO, NiO-Pt, or LiNiO2 have been developed for electrochemical oxidation of hydrogen sulfide in intermediate-temperature solid oxide fuel cells (ITSOFCs). All catalysts exhibited good electrical conductivity and catalytic activity at operating temperature. Composite NiO catalysts were found to be more active and have lower over potential and higher current density than pure Pt although the electrical conductivity of NiO itself is lower than that of Pt. This problem has been overcome by either admixing as high as 10% (by mass) Ag powder into NiO cathode layer or using composite NiO catalysts such as NiO-Pt and LiNiO2 catalysts. Composite catalysts like NiO with Ag, electrolyte and starch admixed, NiO-Pt, which was prepared from a mixture of NiO and Pt powders, by admixing electrolyte and starch, and LiNiO2, which is derived from the reac-tion of LiOH?H2O and NiO with electrolyte and starch admixed have been shown to be feasible and effective in an intermediate-temperature H2S-air fuel cell. A fuel cell using Li2SO4-based proton-conducting membrane as electro-lyte, metal sulfides as anode catalysts, and composite NiO as cathode catalysts produced a maximum current density about 300mA?cm－2 and maximum power density over 80 mW?cm－2 at 680℃.

Key words: cathode, catalyst, fuel cell, hydrogen sulfide

摘要： Cathode catalysts comprising composite NiO, NiO-Pt, or LiNiO2 have been developed for electrochemical oxidation of hydrogen sulfide in intermediate-temperature solid oxide fuel cells (ITSOFCs). All catalysts exhibited good electrical conductivity and catalytic activity at operating temperature. Composite NiO catalysts were found to be more active and have lower over potential and higher current density than pure Pt although the electrical conductivity of NiO itself is lower than that of Pt. This problem has been overcome by either admixing as high as 10% (by mass) Ag powder into NiO cathode layer or using composite NiO catalysts such as NiO-Pt and LiNiO2 catalysts. Composite catalysts like NiO with Ag, electrolyte and starch admixed, NiO-Pt, which was prepared from a mixture of NiO and Pt powders, by admixing electrolyte and starch, and LiNiO2, which is derived from the reac-tion of LiOH?H2O and NiO with electrolyte and starch admixed have been shown to be feasible and effective in an intermediate-temperature H2S-air fuel cell. A fuel cell using Li2SO4-based proton-conducting membrane as electro-lyte, metal sulfides as anode catalysts, and composite NiO as cathode catalysts produced a maximum current density about 300mA?cm－2 and maximum power density over 80 mW?cm－2 at 680℃.

关键词: cathode;catalyst;fuel cell;hydrogen sulfide

ZHONG Li, LUO Jingli, K.Chuang. Investigation of Cathode Catalysts for Intermediate-temperature
H₂S-Air Fuel Cells
[J]. .

钟理, 罗京莉, K.Chuang. 中温H₂S-空气燃料电池阴极催化剂的研究[J]. CIESC Journal.

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Investigation of Cathode Catalysts for Intermediate-temperature
H₂S-Air Fuel Cells

中温H₂S-空气燃料电池阴极催化剂的研究

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