Phosphate regulate the microstructure and surface hydroxyl density of nano-titanium dioxide

doi:10.16085/j.issn.1000-6613.2015.05.036

Chemical Industry and Engineering Progree ›› 2015, Vol. 34 ›› Issue (05): 1401-1405.DOI: 10.16085/j.issn.1000-6613.2015.05.036

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Phosphate regulate the microstructure and surface hydroxyl density of nano-titanium dioxide

TAO Yugui, ZHENG Jie, ZHU Longbao, GE Fei, LIANG Mindong

College of Biochemistry Engineering, Anhui Polytechnic University, Wuhu 241000, Anhui, China

Received:2014-11-05 Revised:2014-12-22 Online:2015-05-05 Published:2015-05-05

磷酸盐调控纳米TiO₂微结构及其表面羟基密度

陶玉贵, 郑洁, 朱龙宝, 葛飞, 梁敏东

安徽工程大学生物与化学工程学院, 安徽芜湖 241000

通讯作者: 陶玉贵(1965—),男,硕士,教授,主要研究方向为生物功能材料.E-mailtaoyugui@126.com.
作者简介:陶玉贵(1965—),男,硕士,教授,主要研究方向为生物功能材料.E-mailtaoyugui@126.com.
基金资助:
安徽省自然科学基金(1308085MC51)、安徽省高校自然科学基金重点项目(KJ2012A034)及全国大学生创新创业训练计划(201410363023)项目.

Abstract

Abstract: Titanium dioxide was prepared by adding phosphate in the sol-gel process and acetic acid used as an inducer. The effect of phosphate on nano-titanium dioxide micro-structure and surface hydroxyl density were studied in this paper. The process of phase transition and surface structural change were investigated by powder X-ray diffraction(XRD),Brunauer–Emmett–Teller (BET),X-ray energy-dispersive (EDS),scanning electron microscope (SEM),fourier-transformed infrared (FT-IR) and thermogravimetric analysis (TGA). The results showed that the surface hydroxyl groups of nano-titanium dioxide were significantly increased with the adding amount of phosphate. The surface hydroxyl densities were 10.74nm^-2 and 4.03nm^-2 of the samples calcined at the temperature of 500℃ and 700℃,respectively. However,the control sample with none phosphate was 4.95 D_OH/nm² at 500℃. Moreover,the thermal stability of the phase transition was enhanced by adding phosphate in sol-gel process. Until the phase change temperature reached 800℃ did it have been begun to ransform anatase to rutile. The may be due to the bonding of PO₄^3- in these multidentate modes occupy one full face of [TiO₆] octahedra and inhibit the growing of chain along the opposite edges and hence inhibit the formation of rutile.

Key words: TiO₂ nanoparticle, phosphate, rutile, anatase, surface hydroxyl density

摘要： 以冰乙酸作诱导剂,研究磷酸盐在溶胶-凝胶法合成纳米二氧化钛过程中对其微结构及其表面羟基密度的影响,并利用XRD、BET、EDS、SEM、FT-IR和TGA等方法对二氧化钛相变过程和表面结构变化进行表征.结果表明:合成过程中添加磷酸根可增加纳米二氧化钛的表面羟基密度,500℃、700℃煅烧6h,其表面羟基密度分别为10.74nm^-2、4.03nm^-2,而对照样在500℃煅烧条件下其表面羟基密度为4.95nm^-2;同时磷酸根的添加,有利于锐钛型晶相结构的热稳定性,锐钛型向金红石转变的相变温度达800℃.这可能是由于PO₄^3-与TiO₂晶相生长基元[TiO₆]八面体易发生多齿螯合,不利于金红石相形成.

关键词: 纳米TiO₂, 磷酸根, 金红石, 锐钛矿, 表面羟基密度

CLC Number:

TAO Yugui, ZHENG Jie, ZHU Longbao, GE Fei, LIANG Mindong. Phosphate regulate the microstructure and surface hydroxyl density of nano-titanium dioxide[J]. Chemical Industry and Engineering Progree, 2015, 34(05): 1401-1405.

陶玉贵, 郑洁, 朱龙宝, 葛飞, 梁敏东. 磷酸盐调控纳米TiO₂微结构及其表面羟基密度[J]. 化工进展, 2015, 34(05): 1401-1405.

References

[1] Chen X,Selloni A. Introduction:Titanium dioxide(TiO₂) nanomaterials[J]. Chemical Reviews,2014,114(19):9281-9282.

[2] Macwan D P,Dave P N,Chaturvedi S. A review on nano-TiO₂ sol-gel type syntheses and its applications[J]. Journal of Materials Science,2011,46(11):3669-3686.

[3] Thomas A G,Syres K L. Adsorption of organic molecules on rutile TiO₂ and anatase TiO₂ single crystal surfaces[J]. Chemical Society Reviews,2012,41(11):4207-4217.

[4] de Angelis F,di Valentin C,Fantacci S,et al. Theoretical studies on anatase and less common TiO₂ phases:Bulk,surfaces,and nanomaterials[J]. Chemical Reviews,2014,114(19):9708-9553.

[5] Simonsen M E,Li Z,Søgaard E G. Influence of the OH groups on the photocatalytic activity and photoinduced hydrophilicity of microwave assisted sol-gel TiO₂ film[J]. Applied Surface Science,2009,255(18):8054-8062.

[6] Guo M Y,Ng A M C,Liu F,et al. Photocatalytic activity of metal oxides——The role of holes and OH radicals[J]. Applied Catalysis B:Environmental,2011,107(1):150-157.

[7] di Paola A,Bellardita M,Palmisano L,et al. Influence of crystallinity and OH surface density on the photocatalytic activity of TiO₂ powders[J]. Journal of Photochemistry and Photobiology A:Chemistry,2014,273:59-67.

[8] 肖羽堂,李志花,许双双. 非金属元素掺杂二氧化钛纳米管的研究进展[J]. 化工进展,2010,29(7):1235-1240.

[9] Zhao D,Chen C,Wang Y,et al. Surface modification of TiO₂ by phosphate:Effect on photocatalytic activity and mechanism implication[J]. The Journal of Physical Chemistry C,2008,112(15):5993-6001.

[10] 秦旭,井立强,薛连鹏,等. 磷酸对 TiO₂ 纳米粒子光催化剂的改性[J]. 无机化学学报,2008,24(7):1108-1112.

[11] Zhang H,Banfield J F. Understanding polymorphic phase transformation behavior during growth of nanocrystalline aggregates:Insights from TiO₂[J]. The Journal of Physical Chemistry B,2000,104(15):3481-3487.

[12] Mueller R,Kammler H K,Wegner K,et al. OH surface density of SiO₂ and TiO₂ by thermogravimetric analysis[J]. Langmuir,2003,19(1):160-165.

[13] Xian T,Yang H,Dai J F. Preparation,photocatalytic properties and photogenerated hydroxyl radicals of TiO₂ nanoparticles[J]. Nanotechnol. Precis Eng.,2013,11(2):111-117.

[14] Barnard A S,Curtiss L A. Prediction of TiO₂ nanoparticle phase and shape transitions controlled by surface chemistry[J]. Nano Letters,2005,5(7):1261-1266.

[15] Hanaor D A H,Sorrell C C. Review of the anatase to rutile phase transformation[J]. Journal of Materials Science,2011,46(4):855-874.

Phosphate regulate the microstructure and surface hydroxyl density of nano-titanium dioxide

磷酸盐调控纳米TiO₂微结构及其表面羟基密度

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Phosphate regulate the microstructure and surface hydroxyl density of nano-titanium dioxide

磷酸盐调控纳米TiO2微结构及其表面羟基密度

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磷酸盐调控纳米TiO₂微结构及其表面羟基密度