Keito Nakajima scite author profile

Using iACRES, which is an ironmaking system based on the Active Carbon Recycling Energy System concept, to reduce or recycle CO 2 emitted from ironmaking processes, we electrolyzed CO 2 with a metalsupported solid oxide electrolysis cell (MS-SOEC) capable of providing a large cell surface area for the processing of large amounts of CO 2. The MS-SOEC current-density-voltage (I-V) curves reveal a change in slope at around 0.8 V, which is the theoretical decomposition voltage of CO 2. The CO production rate was 0.88 μmol cm − 2 s − 1 when 2.0 V was applied between the cathode and the anode at 800°C, while that for O 2 was 0.44 μmol cm − 2 s − 1 , which is consistent with the stoichiometry for CO 2 electrolysis. The Faraday efficiency was 48% at 900°C. Gas was observed to leak from the cell; this leakage will need to be overcome through improvements in the layer-production process in order to achieve an efficiency close to 100%. On the basis of the cell-based experimental results, the feasibility of a blast furnace based on iACRES and driven by an HTGR (high-temperature gas-cooled reactor) was evaluated. To reduce CO 2 emissions by 30.0%, the required MS-SOEC surface area was estimated to be 8.30 × 10 4 and 3.98 × 10 4 m 2 with 968 and 480 MWth of HTGR thermal output under Faraday efficiency of 48% and 100%, respectively. We confirmed that iACRES using MS-SOEC contributes to realizing low-carbon ironmaking by recycling CO 2 and reducing its emissions into the atmosphere.

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Keito Nakajima

Effect of Substrate Size on the Electrochemical Properties of Boron-doped Diamond Powders for Screen-printed Diamond Electrode

Carbon Dioxide Reduction on a Metal-Supported Solid Oxide Electrolysis Cell

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