Pd/TiO_2/棉花纤维复合催化材料的制备与性能研究
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摘要
先通过浸渍-提拉法将纳米TiO_2对棉花纤维表面进行修饰,再通过浸渍-NaBH4还原法将Pd纳米颗粒沉积在TiO_2/棉花纤维(TC)表面,制备得到Pd/TiO_2/棉花纤维复合催化材料(PTC)。所制备的复合催化材料用于室温氧化分解甲醛,研究了Pd负载量对催化性能的影响。结果表明,PTC催化材料具有远低于粉末状样品的气阻,此特点对催化材料的实际应用具有非常大的优势;该催化材料能有效室温分解甲醛成CO_2和H_2O。PTC催化材料的催化活性随Pd含量(0.25%~1.0%,质量分数)的增加而增加。鉴于PTC催化材料具有低气阻、轻质、使用灵活的属性和良好催化效率以及载体棉花原料来源广泛、成本低等优点,具有良好的实际应用于室内空气净化和相关催化过程的潜力。
Cotton fibers were firstly treated by nano TiO_2 coating via a dip-coating method, and then Pd nanoparticles(NPs) weredeposited onto the surface of TiO_2/cotton fiber(TC) to acquire the Pd/TiO_2/cotton fiber composite(PTC) catalyst by a combinedimpregnation and NaBH4-reduction method. The obtained PTC sample was used for room-temperature catalytic oxidation of formaldehyde(HCHO) and the influence of Pd content on catalytic activity was investigated. The results reveal that the air resistance of PTC catalyst ismuch lower than that of the powder-like sample, which is of vital importance for its actual application, and HCHO can be catalyticallydecomposed into CO_2 and H_2O over PTC. The catalytic activity of PTC increases with increasing of Pd content in the range of 0.25 wt%~1.0 wt%. Owing to the merits of low air resistance, light mass, flexible properties and good efficiency of the PTC catalyst, it canbe a good candidate in actual indoor air purification and related catalytic processes.
Cotton fibers were firstly treated by nano TiO_2 coating via a dip-coating method, and then Pd nanoparticles(NPs) weredeposited onto the surface of TiO_2/cotton fiber(TC) to acquire the Pd/TiO_2/cotton fiber composite(PTC) catalyst by a combinedimpregnation and NaBH4-reduction method. The obtained PTC sample was used for room-temperature catalytic oxidation of formaldehyde(HCHO) and the influence of Pd content on catalytic activity was investigated. The results reveal that the air resistance of PTC catalyst ismuch lower than that of the powder-like sample, which is of vital importance for its actual application, and HCHO can be catalyticallydecomposed into CO_2 and H_2O over PTC. The catalytic activity of PTC increases with increasing of Pd content in the range of 0.25 wt%~1.0 wt%. Owing to the merits of low air resistance, light mass, flexible properties and good efficiency of the PTC catalyst, it canbe a good candidate in actual indoor air purification and related catalytic processes.
引文
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[3]Le Y,Guo D,Cheng B et al.Applied Surface Science[J],2013,274:110
[4]Lam R C W,Leung M K H,Leung D Y C et al.Solar Energy Materials and Solar Cells[J],2007,91(1):54
[5]Liang W J,Li J,Li J X et al.Journal of Hazardous Materials[J],2010,175(1-3):1090
[6]Zhang C B,He H.Catalysis Today[J],2007,126(3-4):345
[7]Huang H B,Leung D Y C.ACS Catalysis[J],2011,1(4):348
[8]An N H,Zhang W L,Yuan X L et al.Chemical Engineering Journal[J],2013,215-216:1
[9]Huang Z W,Gu X,Cao Q Q et al.Angewandte Chemie International Edition[J],2012,127(17):4274
[10]Tang X F,Li YG,Huang X M et al.Applied Catalysis B:Environmental[J],2006,62(3-4):265
[11]Sekine Y.Atmospheric Environment[J],2002,36(35):5543
[12]Wang J L,Li J G,Jiang C J et al.Applied Catalysis B:Environmental[J],2017,204:147
[13]Nie L H,Yu J G,Li X Y et al.Environmental Science&Technology[J],2013,47(6):2777
[14]Zhang C B,He H,Tanaka K I.Catalysis Communications[J],2005,6(3):211
[15]Chen B B,Shi C,Crocker M et al.Applied Catalysis B:Environmental[J],2013,132-133:245
[16]Zhang C B,Li Y B,Wang Y F et al.Environmental Science&Technology[J],2014,48(10):5816
[17]Nie L H,Yu J G,Fu J W.ChemCatChem[J],2014,6(7):1983
[18]Nie L H,Zheng Y Q,Yu J G.Dalton Transactions[J],2014,43:12935
[19]Mejia M I,Marin J M,Restrepo G et al.Applied Catalysis B:Environmental[J],2009,91(1-2):481
[20]Rahal R,Pigot T,Foix D et al.Applied Catalysis B:Environmental[J],2011,104(3-4):361
[21]Nie L H,Wang J,Yu J G.RSC Advances[J],2017,7:21 389
[22]Du Junchen(杜君臣).Rare Metal Materials and Engineering(稀有金属材料与工程)[J],2017,46(1):252
[23]Zhao Wanguo(赵万国),Li Wen(李文),Lu Lilin(鲁礼林)et al.Rare Metal Materials and Engineering(稀有金属材料与工程)[J],2016,45(12):3160
[24]Thommes M,Kaneko K,Neimark A V et al.Pure and Applied Chemistry[J],2015,87:1051