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氧化鉍基鈣鈦礦陰極材料用於中溫型燃料電池之研究

Bismuth-based perovskite as cathode materials for intermediate -temperature solid oxide fuel cells

黃德榮(Te-Jung Huang)
指導教授 : 韋文誠
國立臺灣大學/工學院/材料科學與工程學研究所/碩士(2013年)
https://doi.org/10.6342/NTU.2013.02799
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摘要

本研究選擇鉍鍶鐵及鉍鍶鈷鐵鈣鈦礦之陰極材料,運用於中溫型燃料電池 (600°C – 800°C),使用X光繞射、電導率量測、離導率量測、熱膨脹,以及全電池電能輸出量測予以分析。從XRD分析中,成功利用EDTA-檸檬酸鰲合法製備出單一相鈣鈦礦結構粉體。其中,鍶摻雜鐵酸鉍的燒結樣品中,以50 %鍶摻雜鐵酸鉍的樣品在800°C時的電導率及離導率分別為1.5 S cm-1、0.011 S cm-1為最佳;在鍶鈷共摻雜鐵酸鉍燒結樣品中,以鍶摻雜50 %、鈷摻雜20 %的樣品在800°C時電導率及離導率分別為5.4 S cm-1、0.032 S cm-1為最佳。熱分析的結果顯示,鍶摻雜鐵酸鉍的熱膨脹係數隨鍶摻雜的量增加而增加,其從10.0 ppm K-1至15.1ppm K-1。而以鍶鈷共摻雜鐵酸鉍樣品中,熱膨脹係數以鈷摻雜20 % 達到最大,其值為19.1 ppm K-1。S50C20 在所有樣品中擁有最低的極化電阻值,0.1 Ω cm2。以鑭鍶鈷鐵作為陰極的單一陽極支撐全電池為標準電池,其I-V量測的結果中,以S50及S50C20為陰極組成的全電池,輸出分別為361 mW cm-2、405 mW cm-2,其皆高於標準電池的輸出,353 mW cm-2。

關鍵字

固態電解質燃料電池 鈣鈦礦 鐵酸鉍 陰極

並列摘要

Two series perovskites, Bi1-xSrxFeO3-δ (x = 0.1-0.5) and Bi0.5Sr0.5CoyFe1-yO3-δ (y = 0-0.2), have been synthesized by EDTA-citric complexing method and characterized in intermediate-temperature range (600 to 800°C) by X-ray diffraction, electrical property study, thermal analysis and cell testing. The results show single-phase perovskite structure offering CTE values from 10.0 to 19.1 ppmk-1. Two samples S50 and S50C20 perform maximal electrical and ionic conductivities among the series. Polarization resistance from Nyquist plot depicts that S50C20 has a lowest value of 0.10 Ω.cm2. The cells with S50 or S50C20 cathode comparing to the standard cell with La0.6Sr0.4Co0.2Fe0.8O3-δ cathode show the power density 361 mWcm-2,405 mW cm-2 and 353 mW cm-2,respectively. The cells with Bi-base cathodes have a power density higher then that of STD cell.

並列關鍵字

SOFC perovskite bismuth ferrite cobalt cathode

參考文獻

1J. P. P. Huijsmans, F. P. F. Van Berkel, G. M. Christine, “Intermediate temperature SOFC-A promise for the 21st century,” J. Power sources, [71] 107-10 (1988).
2J. M. Ralph, C. Rossignol, R. Kumar, “Cathode materials for reduced-temperature SOFCs,” J. Electrochem. Soc., [150] A1518-22 (2003).
3W. Zhou, R. Ran, Z. P. Shao, Progress in understanding and development of Ba0.5Sr0.5Co0.2Fe0.8O3-δ–based cathode for intermediate-temperature solid oxide fuel cells: a review,” J. Power Sources, [192] 231-46 (2009).
4Z. P. Shao, S. M. Haile, A high-performance cathode for the next generation of solid oxide fuel cells,” Nature 431 [7005] 170-3 (2004).
5K. T. Lee, A. Manthiram, “A comparison of Ln0.6Sr0.4CoO3-δ (Ln = La, Pr, Nd, Sm, and Gd) as cathode materials for intermediate temperature solid oxide fuel cells,” J. Electrochem. Soc. [153] A794-8 (2006)

被引用紀錄

Chen, Y. H. (2015). 中溫型燃料電池鉍基陰極之合成、材料特性及電性研究 [master's thesis, National Taiwan University]. Airiti Library. https://doi.org/10.6342/NTU.2015.01788

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