èŠ‚ç‚¹æ–‡çŒ®

Preparation and Characterization of Component Materials for Intermediate Temperature Solid Oxide Fuel Cell by Glycine-Nitrate Process

æŽ¨è CAJä¸‹è½½
PDFä¸‹è½½
ä¸æ”¯æŒè¿…é›·ç‰ä¸‹è½½å·¥å…·ï¼Œè¯·å–æ¶ˆåŠ é€Ÿå·¥å…·åŽä¸‹è½½ã€‚

ã€ä½œè€…ã€‘ åˆ˜è£è¾‰ï¼› æœé’å±±ï¼› é©¬æ–‡ä¼šï¼› çŽ‹åŽï¼› æ¨æ–Œï¼› æˆ´æ°¸å¹´ï¼› é©¬å¦èŠï¼›

ã€Authorã€‘ Liu Ronghui , Du Qingshan , Ma Wenhui , Wang Hua Yang Bin , Dai Yongnian , Ma Xueju ( Faculty of Materials and Metallurgical Engineering , Kunming University of Science and Technology , Kunming 650093 , China ; National Engineering Laboratory of Vacuum Metallurgy , Kunming 650093 , China )

ã€æœºæž„ã€‘ Faculty of Materials and Metallurgical Engineering Kunming University of Science and Technologyï¼› National Engineering Laboratory of Vacuum Metallurgyï¼› Kunming 650093ï¼› Chinaï¼› Faculty of Materials and Metallurgical Engineeringï¼› Kunming University of Science and Technologyï¼›

ã€æ‘˜è¦ã€‘ <æ£>La1-xSrxGa1-y MgyO3-Î´(LSGM) electrolyte, La1-xSrxCr1-y MnyO3-Î´( LSCM ) anode and La1-xSrxFe1-y MnyO3-aaaaaaa(LSFM) cathode materials were all synthesized by glycine-nitrate process (GNP). The microstructure and characteristics of LSGM, LSCM and LSFM were tested via X-ray diffraction(XRD), scanning electron microcopy (SEM), A C impedance and four-probe direct current techniques. XRD shows that pure perovskite phase LSGM electrolyte and electrode (LSCM anode and LSFM cathode) materials were prepared after being sintered at 1400â„ƒfor 20 h and at 1000â„ƒfor 5 h, respectively. The max conductivities of LSGM (ionic conductivity), LSCM (total conductivity) and LSFM (total conductivity) materials are 0.02, 10, 16 SÂ·cm-1 in the air below 850â„ƒ, respectively. The conductivity of LSCM becomes smaller when the atmosphere changes from air to pure hydrogen at the same temperature and it decreases with the temperature like metal. The porous and LSGM-based LSCM anode and LSFM cathode films were prepared by screen printing method, and the sintering temperatures for them were 1300 and 1250â„ƒ, respectively. LSGM and electrode (LSCM and LSFM) materials have good thermal and chemical compatibility.æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ La1-xSrxGa1-y MgyO3-Î´(LSGM) electrolyte, La1-xSrxCr1-y MnyO3-Î´( LSCM ) anode and La1-xSrxFe1-y MnyO3-aaaaaaa(LSFM) cathode materials were all synthesized by glycine-nitrate process (GNP). The microstructure and characteristics of LSGM, LSCM and LSFM were tested via X-ray diffraction(XRD), scanning electron microcopy (SEM), A C impedance and four-probe direct current techniques. XRD shows that pure perovskite phase LSGM electrolyte and electrode (LSCM anode and LSFM cathode) materials were prepared after being sintered at 1400â„ƒfor 20 h and at 1000â„ƒfor 5 h, respectively. The max conductivities of LSGM (ionic conductivity), LSCM (total conductivity) and LSFM (total conductivity) materials are 0.02, 10, 16 SÂ·cm-1 in the air below 850â„ƒ, respectively. The conductivity of LSCM becomes smaller when the atmosphere changes from air to pure hydrogen at the same temperature and it decreases with the temperature like metal. The porous and LSGM-based LSCM anode and LSFM cathode films were prepared by screen printing method, and the sintering temperatures for them were 1300 and 1250â„ƒ, respectively. LSGM and electrode (LSCM and LSFM) materials have good thermal and chemical compatibility.æ›´å¤š è¿˜åŽŸ

ã€å…³é”®è¯ã€‘ intermediate temperature solid oxide fuel cellï¼› glycine-nitrate processï¼› properties of materialsï¼› rare earthsï¼›
ã€Key wordsã€‘ intermediate temperature solid oxide fuel cellï¼› glycine-nitrate processï¼› properties of materialsï¼› rare earthsï¼›

ã€åŸºé‡‘ã€‘ Project supported by the National Natural Science Foundation of China (50204007);the Foundation of Yunnan Province (2005PY01-33)

ã€æ–‡çŒ®å‡ºå¤„ã€‘ Journal of Rare Earths ,ç¨€åœŸå¦æŠ¥(è‹±æ–‡ç‰ˆ) , ç¼–è¾‘éƒ¨é‚®ç®± ,2006å¹´S1æœŸ

ã€åˆ†ç±»å·ã€‘TM911.4
ã€è¢«å¼•é¢‘æ¬¡ã€‘4
ã€ä¸‹è½½é¢‘æ¬¡ã€‘42

çŸ¥ç½‘èŠ‚ä¸‹è½½

èŠ‚ç‚¹æ–‡çŒ®ä¸ï¼š

æœ¬æ–‡é“¾æŽ¥çš„æ–‡çŒ®ç½‘ç»œå›¾ç¤º:

æœ¬æ–‡çš„å¼•æ–‡ç½‘ç»œ

èŠ‚ç‚¹æ–‡çŒ®