Coking-free direct-methanol-flame fuel cell with traditional nickel-cermet anode

Liangliang Sun; Yong Hao; Chunming Zhang; Ran Ran; Zongping Shao

doi:10.1016/j.ijhydene.2010.05.048

Coking-free direct-methanol-flame fuel cell with traditional nickel-cermet anode

Liangliang Sun, Yong Hao, Chunming Zhang, Ran Ran, Zongping Shao

College of Chemical Engineering

Research output: Contribution to journal › Article › peer-review

55 Scopus citations

Abstract

This paper presents a systematic study of a direct-flame solid oxide fuel cell (DF-SOFC) operating on methanol and ethanol flames by SEM, EIS, I-V polarization and mass spectrometer (MS) characterizations and numerical simulation. The experimental study demonstrated that, by adopting a conventional Ni + Sm_0.2Ce_0.8O_1.9 (SDC) anode, irreversible carbon deposition and a drop of cell performance was observed when running the cell on an ethanol flame, while no carbon was deposited by operating on a methanol flame. Fuel cell stability tests indicated significant degradation in performance after 3 h of operation on an ethanol flame, while no degradation was observed after 30 h of operation on a methanol flame. A simple qualitative explanation of the difference observed in the electrochemical performance for the fuel cell operating on a methanol flame and an ethanol flame is presented based on numerical simulation.

Original language	English
Pages (from-to)	7971-7981
Number of pages	11
Journal	International Journal of Hydrogen Energy
Volume	35
Issue number	15
DOIs	https://doi.org/10.1016/j.ijhydene.2010.05.048
State	Published - Aug 2010

Keywords

Carbon deposition
Direct-flame fuel cells
Hydrocarbons
Solid oxide fuel cells

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.ijhydene.2010.05.048

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title = "Coking-free direct-methanol-flame fuel cell with traditional nickel-cermet anode",

abstract = "This paper presents a systematic study of a direct-flame solid oxide fuel cell (DF-SOFC) operating on methanol and ethanol flames by SEM, EIS, I-V polarization and mass spectrometer (MS) characterizations and numerical simulation. The experimental study demonstrated that, by adopting a conventional Ni + Sm0.2Ce0.8O1.9 (SDC) anode, irreversible carbon deposition and a drop of cell performance was observed when running the cell on an ethanol flame, while no carbon was deposited by operating on a methanol flame. Fuel cell stability tests indicated significant degradation in performance after 3 h of operation on an ethanol flame, while no degradation was observed after 30 h of operation on a methanol flame. A simple qualitative explanation of the difference observed in the electrochemical performance for the fuel cell operating on a methanol flame and an ethanol flame is presented based on numerical simulation.",

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author = "Liangliang Sun and Yong Hao and Chunming Zhang and Ran Ran and Zongping Shao",

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AU - Sun, Liangliang

AU - Hao, Yong

AU - Zhang, Chunming

AU - Ran, Ran

AU - Shao, Zongping

PY - 2010/8

Y1 - 2010/8

N2 - This paper presents a systematic study of a direct-flame solid oxide fuel cell (DF-SOFC) operating on methanol and ethanol flames by SEM, EIS, I-V polarization and mass spectrometer (MS) characterizations and numerical simulation. The experimental study demonstrated that, by adopting a conventional Ni + Sm0.2Ce0.8O1.9 (SDC) anode, irreversible carbon deposition and a drop of cell performance was observed when running the cell on an ethanol flame, while no carbon was deposited by operating on a methanol flame. Fuel cell stability tests indicated significant degradation in performance after 3 h of operation on an ethanol flame, while no degradation was observed after 30 h of operation on a methanol flame. A simple qualitative explanation of the difference observed in the electrochemical performance for the fuel cell operating on a methanol flame and an ethanol flame is presented based on numerical simulation.

AB - This paper presents a systematic study of a direct-flame solid oxide fuel cell (DF-SOFC) operating on methanol and ethanol flames by SEM, EIS, I-V polarization and mass spectrometer (MS) characterizations and numerical simulation. The experimental study demonstrated that, by adopting a conventional Ni + Sm0.2Ce0.8O1.9 (SDC) anode, irreversible carbon deposition and a drop of cell performance was observed when running the cell on an ethanol flame, while no carbon was deposited by operating on a methanol flame. Fuel cell stability tests indicated significant degradation in performance after 3 h of operation on an ethanol flame, while no degradation was observed after 30 h of operation on a methanol flame. A simple qualitative explanation of the difference observed in the electrochemical performance for the fuel cell operating on a methanol flame and an ethanol flame is presented based on numerical simulation.

KW - Carbon deposition

KW - Direct-flame fuel cells

KW - Hydrocarbons

KW - Solid oxide fuel cells

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SN - 0360-3199

VL - 35

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JO - International Journal of Hydrogen Energy

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Coking-free direct-methanol-flame fuel cell with traditional nickel-cermet anode

Abstract

Keywords

UN SDGs

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