化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
11期
4325-4332
,共8页
光化学%催化剂%微反应器%二氧化钛%铜离子掺杂%甲基橙
光化學%催化劑%微反應器%二氧化鈦%銅離子摻雜%甲基橙
광화학%최화제%미반응기%이양화태%동리자참잡%갑기등
photochemistry%catalyst%planar microreactor%titanium dioxide%copper ion doping%methyl orange
将微反应器技术应用于光催化反应是一项新兴且极具潜力的技术创新。采用金属蚀刻技术制造了板式微反应器,并通过溶胶-凝胶法在微反应器中负载了铜离子掺杂改性的TiO2光催化剂涂层。使用X射线衍射分析、扫描电子显微镜以及紫外-可见漫反射吸收光谱对催化剂进行表征,并以甲基橙的降解反应来评价微反应器的光催化效果。结果表明,铜离子掺杂能够有效提高微反应器的光催化性能,掺杂浓度为0.04%(摩尔比于Ti)时效果最优,能够在90 s的停留时间内使初始浓度为10 mg·L-1的甲基橙溶液降解45%;光催化微反应器中甲基橙的降解过程为不完全氧化的动力学一级反应,其反应速率常数(k)远高于常规反应器体系,并随着甲基橙溶液初始浓度(C0)的减小而增大,且lnk-lnC0具有良好的线性关系。
將微反應器技術應用于光催化反應是一項新興且極具潛力的技術創新。採用金屬蝕刻技術製造瞭闆式微反應器,併通過溶膠-凝膠法在微反應器中負載瞭銅離子摻雜改性的TiO2光催化劑塗層。使用X射線衍射分析、掃描電子顯微鏡以及紫外-可見漫反射吸收光譜對催化劑進行錶徵,併以甲基橙的降解反應來評價微反應器的光催化效果。結果錶明,銅離子摻雜能夠有效提高微反應器的光催化性能,摻雜濃度為0.04%(摩爾比于Ti)時效果最優,能夠在90 s的停留時間內使初始濃度為10 mg·L-1的甲基橙溶液降解45%;光催化微反應器中甲基橙的降解過程為不完全氧化的動力學一級反應,其反應速率常數(k)遠高于常規反應器體繫,併隨著甲基橙溶液初始濃度(C0)的減小而增大,且lnk-lnC0具有良好的線性關繫。
장미반응기기술응용우광최화반응시일항신흥차겁구잠력적기술창신。채용금속식각기술제조료판식미반응기,병통과용효-응효법재미반응기중부재료동리자참잡개성적TiO2광최화제도층。사용X사선연사분석、소묘전자현미경이급자외-가견만반사흡수광보대최화제진행표정,병이갑기등적강해반응래평개미반응기적광최화효과。결과표명,동리자참잡능구유효제고미반응기적광최화성능,참잡농도위0.04%(마이비우Ti)시효과최우,능구재90 s적정류시간내사초시농도위10 mg·L-1적갑기등용액강해45%;광최화미반응기중갑기등적강해과정위불완전양화적동역학일급반응,기반응속솔상수(k)원고우상규반응기체계,병수착갑기등용액초시농도(C0)적감소이증대,차lnk-lnC0구유량호적선성관계。
Applying microreactor technology to photocatalytic reactions is a novel and potential technical innovation. Photocatalytic planar microreactors were fabricated by metal etching technology, and copper ion doped TiO2 was immobilized as coatings by the sol-gel method. X-ray diffraction, scanning electron microscope and UV-visible diffuse reflection were used for characterization of photocatalyst. The microreactors were tested for the degradation of methyl orange and the optimal doping concentration of copper ion was found to be 0.04% (mole ratio to Ti). The degradation ratio of methyl orange with an initial concentration of 10 mg·L-1 could reach 45% within 90 s in the microreactor. Degradation ratios of methyl orange in microreactors under controlled irradiation were measured, and the copper ion doped photocatalytic microreactors showed better utilization of irradiation energy. The study of kinetics illustrated that the degradation of methyl orange in the microreactors was a first order reaction of incomplete oxidation with a much greater rate constant (k) comparing to regular reactors. The rate constant increased with the decreasing of initial concentration (C0), and there was a good linear relationship of lnk and lnC0.