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"Fuel cell"

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"Fuel cell"

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Regular Paper

The direct utilization of steelmaking by-product gases in solid oxide fuel cells (SOFCs) offers a promising pathway to improve energy efficiency and reduce carbon emissions in the steel industry. In this study, a Sr-deficient and Ni-doped double perovskite oxide, Sr1.95Fe1.35Ni0.15Mo0.5O6-δ (SFNM), was investigated as an anode material for direct Linz-Donawitz converter gas (LDG)-fueled SOFCs. A single-phase double perovskite structure was successfully obtained after calcination at 1,200°C for 12 h, while exsolved metallic Ni nanoparticles were generated on the SFNM surface after reduction at 800°C. Electrochemical performance was evaluated using H2, simulated-LDG, and CO/CO2 (85:15) fuels at 800°C. The maximum power densities achieved were 1.23, 0.70, and 0.40 W cm-2 for H2, simulated-LDG, and CO/CO2 fuels, respectively. Although CO-containing fuels exhibited lower opencircuit voltages and power outputs than H2, the SFNM anode maintained stable operation and appreciable performance under direct simulated-LDG utilization. Impedance analysis revealed that the increased polarization resistance in simulated-LDG and CO/CO2 atmospheres was mainly associated with fuel adsorption/desorption and gas diffusion, while interfacial charge-transfer resistance remained relatively small. The superior performance obtained with simulated-LDG compared to the CO/CO2 mixture was attributed to the presence of a small amount of H2, which facilitated anode reaction kinetics. These results demonstrate that SFNM is a promising mixed ionic-electronic conductor anode for the direct electrochemical conversion of CO-rich steelmaking by-product gases into electricity.
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First-Principles Calculations for Design of Efficient Electrocatalysts
Dong Yeon Kim
J Electr Electron Mater 2021;34(6):393-400.   Published online November 1, 2021
DOI: https://doi.org/10.4313/JKEM.2021.34.6.1
As the recent climate problems are getting worse year after year, the demands for clean energy materials have highly increased in modern society. However, the candidate material classes for clean energy expand rapidly and the outcomes are too complex to be interpreted at laboratory scale (e.g., multicomponent materials). In order to overcome these issues, the firstprinciples calculations are becoming attractive in the field of material science. The calculations can be performed rapidly using virtual environments without physical limitations in a vast candidate pool, and theory can address the origin of activity through the calculations of electronic structure of materials, even if the structure of material is too complex. Therefore, in terms of the latest trends, we report academic progress related to the first-principles calculations for design of efficient electrocatalysts. The basic background for theory and specific research examples are reported together with the perspective on the design of novel materials using first-principles calculations.
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Characterization and Fabrication of La(Sr)Fe(Co)O3-δ Infiltrated Cathode Support-Type Solid Oxide Fuel Cells
Kuk-jin Hwang, Min Kyu Kim, Hanbit Kim, Tae Ho Shin
J Electr Electron Mater 2019;32(6):501-506.   Published online November 1, 2019
To overcome the limitations of the conventional Ni anode-supported SOFCs, various types of ceramic anodes have been studied. However, these ceramic anodes are difficult to commercialize because of their low cell performances and difficulty in manufacturing anode-support typed SOFCs. Therefore, in this study, to use these ceramic anodes and take advantage of anode-supported SOFC, which can minimize ohmic loss from the thin electrolyte, we fabricated cathode support-typed SOFC. The cathode-support of LSCF-YSZ was prepared by the acid treatment of conventional Ni-YSZ (Yttria-stabilized Zirconia) anode-support, followed by the infiltration of LSCF to YSZ scaffold. The composite of La(Sr)Ti(Ni)O3 and Ce(Mn, Fe)O2 was used as the ceramic anode. The fabricated cathode-supported button cell showed a relatively low power density of 0.207 Wcm-2 at 850℃; however, it is expected to show better performance through the optimization of the infiltration rate and thickness of LSCF-YSZ cathode-support layer.
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The Electrochemical Property of the Single-Chamber Solid Oxide Fuel Cell Based on a Zirconia Electrolyte
Hee Jung Park, Jong Hoon Joo, Jae Kyo Yang, Yun Ho Jin, Kyu Hyoung Lee
J Electr Electron Mater 2016;29(8):510-515.   Published online August 1, 2016
Single-chamber solid oxide fuel cells (SC-SOFCs) consist of only one gas chamber, in which both the anode and the cathode are exposed to the same fuel-oxidant mixture. Thus, this configuration shows good thermal and mechanical resistance and allows rapid start-up and -down. In this study, the unit cell consisting of La0.8Sr0.2MnO3 (cathode) / Zr0.84Y0.16O2-x (electrolyte) / Ni-Zr0.84Y 0.16O2-x (anode) was fabricated and its electrochemical property was investigated as a function of temperature and the volume ratio of fuel and oxidant for SC-SOFCs. Impedance spectra were also investigated in order to figure out the electrical characteristics of the cell. As a result, the cell performance was governed by the polarization resistances of the electrodes. The cell exhibited an acceptable cell-performance of 86 mW/cm2 at 800℃ and stable performance for 3 hs under 0.7 V.
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Regular Paper : The Study on Activity Star Problem and Optimum Construction Method Through the Defect Case of Zero Energy House in the Existing Building
Sun Geun Kim, Soon Wook Kwon
J Electr Electron Mater 2015;28(4):262-270.   Published online April 1, 2015
In this paper existing buildings, not a new buildings and house for living people not just a displaying and a viewing, created by the imagine effect or virtual simulation was applied various Active and Passive elements. After constructing zero-energy houses, through default case happened during operation period it is described problems and solutions about field part, work classification, installation by Location part, and Installation equipment part. Since then, to take advantage of this thesis, it``s the purpose of this paper using as the baseline data for building a zero-energy house in another similar case.
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Regular Paper : Porosity Control in LSM Electrode Formation in Layered Plannar SOFC Module
Won Jun Lee, Dong Hun Yeo, Hyo Soon Shin, Dea Yong Jeong
J Electr Electron Mater 2014;27(12):866-870.   Published online December 1, 2014
In solid oxide fuel cell system, yttria-stabilized zirconia is generally adopted as the electrolyte, which has high strength and superior oxygen ion conductivity, and the air electrode and the fuel electrode are attached to this. Recently, new structure of ``layered planar SOFC module`` was suggested to solve there liability problem due to the high temperature stability of a sealing agent and a binding material. In this study to materialize the air electrode in a layered planar SOFC module, the LSM ink was coated to form homogeneous electrode in the channel after the ink preparation. As the porosity control agent, PMMA oractive carbon powder was adopted with use of a commercial dispersant in ethanol. The optimal amounts of both the porosity control agents and the dispersant were determined. Four (4) vol% of the dispersant for the LSM-PMMA case and 15 vol% for LSM-carbon powder showed the lowest viscosities respectively to indicate the best dispersed states of the slurries. With PMMA and carbon powder, sintered LSM ink shows the relatively homogeneous distributions of pores and with increases of the agents, the porosities increased in both cases. From this, it can be thought that the amount of the PMMA or carbon powder could be used to control the porosity of the LSM ink.
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Ceramic Green Sheet and Sintering Properties on Solvent Mixture Rate of Electrolyte for Solid Oxide Fuel Cells Fabrication
Bong Hwa Moon, Kyung Min Lee, Kyoung Tae Lim, Chung Hwan Lee, Heun Young Lee, Jung Rag Yoon
J Electr Electron Mater 2012;25(6):426-430.   Published online June 1, 2012
The properties of green sheet were investigated in order to understanding an effects of organic solvent mixture ratio for solid oxide fuel cells fabrication, The purpose of this work is to optimize the slurry condition using the design of experiment to improve green sheet properties. The elongation increased with increasing amount of binder and solvent. With increasing amount of solvent, the air permeability increased but the tensile strength decreased. The best properties of the green sheet appeared amount of the binder 17 wt%, solvent 35 wt% and powder 48 wt%. The optimum condition of green and sintered density for solid oxide fuel cells fabrication was obtained in the sample pressured at 800kgf/㎠.
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Dynamic Transient Phenomena of a Proton Exchange Membrane Fuel Cell
Ying Lee, Yong Sung Choi, You Sai Zhang, Kyung Sup Lee
J Electr Electron Mater 2010;23(7):530-533.   Published online July 1, 2010
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Effect of the Coating and Annealing on Noncorrosive of Fuel Cell Separator
J Electr Electron Mater 2007;20(11):1000-1003.   Published online November 1, 2007
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Analysis on the Fuel Cell Performance by the Impedance Method
J Electr Electron Mater 2007;20(10):918-923.   Published online October 1, 2007
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