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PrO_y-ZrO₂ Solid Solution: Characterization and Catalytic Oxidation of CO

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ã€Authorã€‘ WANG Yue-Juan YING Yue-Fang FANG Ping MA Jing-Meng HE Mai LUO Meng-Fei* (Institute of Physical Chemistry, Zhejiang Key Laboratory for Reactive Chemistry on Solid Surfaces, Zhejiang Normal University, Jinhua, Zhejiang 321004)

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ã€æ‘˜è¦ã€‘ é‡‡ç”¨å…±æ²‰æ·€æ³•åˆ¶å¤‡äº†ä¸åŒPr/Zræ¯”çš„PrOy-ZrO2å›ºæº¶ä½“,ç”¨æ¿€å…‰æ‹‰æ›¼å…‰è°±(Raman)ã€X-å°„çº¿ç²‰æœ«è¡å°„(XRD)ã€ç´«å¤–å¯è§å¸æ”¶å…‰è°±(UV-Vis)ç‰æŠ€æœ¯å¯¹å›ºæº¶ä½“è¿›è¡Œäº†ç‰©ç›¸ç»“æž„è¡¨å¾å¹¶é€‰æ‹©COæ°§åŒ–ä½œä¸ºæ¨¡åž‹ååº”è€ƒå¯Ÿäº†å›ºæº¶ä½“çš„å‚¬åŒ–æ€§èƒ½ã€‚ç»“æžœè¡¨æ˜Ž,éšç€Prå«é‡çš„å¢žåŠ ,æ— å®šå½¢ZrO2è½¬åŒ–ä¸ºæ™¶ç›¸ZrO2çš„æ¸©åº¦æé«˜ã€çƒæ•ˆåº”ä¸‹é™,è€ŒPrOy-ZrO2å›ºæº¶ä½“çš„ç‰©ç›¸ç»“æž„ä»Žå•æ–œç›¸é€æ¥å‘å››æ–¹å’Œç«‹æ–¹ç›¸è½¬å˜ã€‚XRDå’ŒRamanå…‰è°±å¾—åˆ°çš„ç‰©ç›¸ç»“æž„çš„å·®åˆ«æ˜¯PrOy-ZrO2å›ºæº¶ä½“çš„è¡¨å±‚å’Œä½“ç›¸ç»“æž„ä¸ä¸€è‡´é€ æˆçš„,PrOy-ZrO2å›ºæº¶ä½“è¡¨å±‚æ›´æ˜“ç”Ÿæˆä½Žå¯¹ç§°æ€§çš„ç‰©ç›¸,è€Œä¸”ä¹Ÿå®¹æ˜“ç”Ÿæˆéžæ™¶ç›¸çš„ç‰©ç›¸ã€‚COæ°§åŒ–å®žéªŒè¡¨æ˜ŽPrOy-ZrO2å›ºæº¶ä½“çš„å‚¬åŒ–æ´»æ€§ä¸Žæ ·å“çš„ç»„æˆæœ‰å¾ˆå¤§å…³ç³»,å…¶ä¸é«˜æ¸©åŒºå’Œä½Žæ¸©åŒºåˆ†åˆ«æ˜¯PZ-30å’ŒPZ-50çš„COæ°§åŒ–æ´»æ€§æœ€é«˜ã€‚æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ Characterization for PrOy-ZrO2 solid solutions prepared by coprecipitation was performed by means of Raman, XRD, UV-Vis and CO oxidation. It is found that with increasing content of Pr, crystallization temperature of amorphous ZrO2 increases and heating effect of crystallization decreases. At higher Pr content, phase transformation towords a higher-symmetrical phase (tetragonal or cubic) was observed. The phase composition obtained by Raman spectra is different from that by XRD, which implies a structure difference between the surface and the bulk of the samples. The CO oxidation activity highly depends on the content of Pr. For CO oxidation, PZ-30 presents the best performance at high reaction temperature, while PZ-50 presents the best performance at low reaction temperature.æ›´å¤š è¿˜åŽŸ