Abstract
The study examines the effect of using low nickel (Ni) with high ceria (CeO2) anode content towards the oxidation of H2 and CH4 fuel by evaluating the activation energy of the ohmic process and charge transfer process. Using a micro-tubular solid oxide fuel cell (MT-SOFC), the anodes are made up of 50% YSZ with varying NiO:CeO2 percentages from 0% NiO, 50% CeO2 to 50% NiO, 0% CeO2. The performance is measured based on maximum power density (MPD), electrochemical impedance spectroscopy (EIS) and activation energy, Ea of the ohmic (Rohm) and charge transfer (Rct) processes. We found that by lowering the Ni content to lower than 50% NiO, anode conductivity will drop by 7-fold. An anode containing 37.5% NiO, 12.5% CeO2 yield MPD of 41.1 and 2.9 mW cm−2 when tested on H2 and CH4 fuels thus have the lowest Ni content without an abrupt negative effect on the MPD and EIS. The significant effect of conductivity drops on MPD and EIS are observed to occur at 25% NiO, 25% CeO2 and lower NiO content. However, anode content of 25% NiO, 25% CeO2 has the lowest Ea for Rct (29.74 kJ mol−1) for operation in CH4, making it the best anode composition to oxidize CH4. As a conclusion, an anode containing 25% NiO:25% CeO2:50% YSZ and 37.5% NiO:12.5% CeO2:50% YSZ shows promising results in becoming the low Ni anode for coking-tolerant SOFC.
Highlights
The emission of greenhouse gases, mainly carbon dioxide, from fossil fuel burning has led to climate changes where the global average temperature has been rising by 0.08 ◦ C per decade since 1880 [1]
Hydrocarbon fuel is being actively researched as a fuel for solid oxide fuel cells (SOFCs) due to the high operating temperature of SOFC that sits well in the hydrocarbon reforming region
In this paper, we explored another potential of a high-CeO2 -content Ni–yttria-stabilized zirconia (YSZ) anode of micro-tubular solid oxide fuel cell (MT-SOFC) in order to create a coking-tolerant SOFC anode
Summary
The emission of greenhouse gases, mainly carbon dioxide, from fossil fuel burning has led to climate changes where the global average temperature has been rising by 0.08 ◦ C per decade since 1880 [1]. This emission is mainly attributed to electricity generation by coal burning, involving multiple steps of energy conversion. Sustainability 2021, 13, 13789 fuel is changed to heat, mechanical, and later, electrical energy, losing a small portion of energy due to inefficiency in the energy exchanging process in each step. Producing electricity by means of a fuel cell involves only one step, potentially limiting energy losses due to inefficiency in multiple steps.
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