功能材料
功能材料
공능재료
Journal of Functional Materials
2015年
17期
17087-17091
,共5页
氮钒共掺TiO2%可见光%光催化氧化%甲醛%表征
氮釩共摻TiO2%可見光%光催化氧化%甲醛%錶徵
담범공참TiO2%가견광%광최화양화%갑철%표정
N-V-codoped TiO2%visible light%photocatalytic oxidation%formaldehyde%characterization
以钛酸丁酯为 Ti源,六次甲基四胺为 N源,偏钒酸铵为V源,利用溶胶‐凝胶法制备氮钒共掺杂二氧化钛(N‐V‐TiO2)纳米材料。采用XRD、UV‐Vis、BET、XPS等检测手段对N‐V‐TiO2的晶型比例、元素组成等进行分析,研究其在可见光下催化氧化甲醛气体的性能。结果表明,煅烧温度500℃、掺氮28%、掺钒1%的N‐V‐TiO2具有混晶型结构、比表面积大、对可见光吸收强,催化降解甲醛的效率最高可达到916.%,分别比纯TiO2、掺氮TiO2、掺钒TiO2的效率显著提高。N‐V‐TiO2光氧化效率随甲醛初始浓度增大而减小,光催化反应服从一级反应动力学特征,而且包括吸附和光催化氧化反应两部分,其中光催化氧化为速控步骤;重复5次使用的效率仍然高于单独掺杂TiO2。
以鈦痠丁酯為 Ti源,六次甲基四胺為 N源,偏釩痠銨為V源,利用溶膠‐凝膠法製備氮釩共摻雜二氧化鈦(N‐V‐TiO2)納米材料。採用XRD、UV‐Vis、BET、XPS等檢測手段對N‐V‐TiO2的晶型比例、元素組成等進行分析,研究其在可見光下催化氧化甲醛氣體的性能。結果錶明,煅燒溫度500℃、摻氮28%、摻釩1%的N‐V‐TiO2具有混晶型結構、比錶麵積大、對可見光吸收彊,催化降解甲醛的效率最高可達到916.%,分彆比純TiO2、摻氮TiO2、摻釩TiO2的效率顯著提高。N‐V‐TiO2光氧化效率隨甲醛初始濃度增大而減小,光催化反應服從一級反應動力學特徵,而且包括吸附和光催化氧化反應兩部分,其中光催化氧化為速控步驟;重複5次使用的效率仍然高于單獨摻雜TiO2。
이태산정지위 Ti원,륙차갑기사알위 N원,편범산안위V원,이용용효‐응효법제비담범공참잡이양화태(N‐V‐TiO2)납미재료。채용XRD、UV‐Vis、BET、XPS등검측수단대N‐V‐TiO2적정형비례、원소조성등진행분석,연구기재가견광하최화양화갑철기체적성능。결과표명,단소온도500℃、참담28%、참범1%적N‐V‐TiO2구유혼정형결구、비표면적대、대가견광흡수강,최화강해갑철적효솔최고가체도916.%,분별비순TiO2、참담TiO2、참범TiO2적효솔현저제고。N‐V‐TiO2광양화효솔수갑철초시농도증대이감소,광최화반응복종일급반응동역학특정,이차포괄흡부화광최화양화반응량부분,기중광최화양화위속공보취;중복5차사용적효솔잉연고우단독참잡TiO2。
N‐V‐codoped nanosized TiO2 powders were prepared by the sol‐gel method with tetrabutyl titanate as Ti resource ,hexamethylene tetramine as nitrogen resource and ammonium metavanadate as vanadium resource . N‐V‐TiO2 powders were characterized by XRD , UV‐Vis ,BET and XPS .The photocatalytic decomposition property of N‐V‐TiO2 to formaldehyde under visible light was investigated .The results show that the N‐V‐TiO2 of calcination temperature at 500 ℃ ,the N‐doped amount of 28% ,the V‐doped amount of 1% has the anatase and rutile mix structure ,large specific surface area and strong visible light absorption .The degradation efficien‐cy of formaldehyde was up to 91 6.% ,which was significantly higher than that of TiO2 ,N‐TiO2 and V‐TiO2 re‐spectively .The degradation efficiency of formaldehyde decreased with the increase of its concentration by N‐V‐TiO2 and the photocatalytic reaction was first order and included adsorption and photocatalytic oxidation which was the rate‐controlling step .The degradation efficiency after 5 times reuse by N‐V‐TiO2 was still higher than that of N‐TiO2 and V‐TiO2 .
