(Fe，N)共掺杂TiO<sub>2</sub>红外光谱的电负性原理研究

doi:10.3964/j.issn.1000-0593(2017)07-2305-06

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摘要：采用电负性原理，构建合理的红外光谱模型，对TiO₂红外光谱的振动频率与元素电负性之间的各种经验关系进行探究。采用溶胶-凝胶法制备(Fe，N)共掺杂TiO₂，利用X-射线衍射(XRD)、傅里叶红外光谱(FTIR)对样品的物相和红外光谱进行了表征。XRD物相分析表明当煅烧温度为600 ℃时，TiO₂样品中的无定形结构己基本转化为锐钛矿型结构。随着煅烧温度升高，TiO₂的X射线衍射峰逐渐由宽变窄，衍射强度由弱变强。当煅烧温度为700 ℃时，锐钛矿型的衍射峰基本消失，取而代之的是金红石相的衍射峰，但TiO₂的主晶相并没有发生改变。红外光谱分析表明(Fe，N)共掺杂TiO₂在650～500 cm^-1区间有一个较宽的吸收峰。电负性模拟计算了(Fe，N)共掺杂TiO₂红外光谱的伸缩振动频率，获得了Fe、N掺杂的位置、分子结构和键价特征：首先计算出约化质量μ，然后按照经典力学伸缩力常数k与频率ν之间满足的关系，结合力常数与电负性关系、键级的计算方法，计算了基本单元都是氧八面体的掺杂金红石、锐钛矿TiO₂的分子振动频率。结果表明：通过电负性理论计算的(Fe，N)共掺杂的TiO₂的红外光谱与实验测量的红外光谱的伸缩振动频率比较吻合。

关键词：电负性原理；红外光谱；二氧化钛；掺杂

Abstract：Based on the principle of electronegativity, a reasonable infrared spectrum model is built, and the relationship between the vibration frequency of TiO₂ infrared spectrum and the electronegativity of element is investigated. (Fe, N) codoped TiO₂ samples were prepared with the sol-gel method. The crystalline phase and IR spectra of the samples were characterized with X-ray diffraction and Fourier infrared spectroscopy (FTIR). XRD phase analysis shows that amorphous structure of TiO₂ samples are mainly transformed into anatase structure when the calcination temperature is 600 ℃. As the calcination temperature is increasing, the X-ray diffraction peaks of TiO₂ gradually become narrower, with greater intensity, and gradually increasing crystallinity of TiO₂. When the calcination temperature is 700 ℃, the diffraction peaks of anatase disappear, only the diffraction peaks of rutile phase can be observed. infrared spectrum indicate that there exists a wider absorption peak in the range of 650～500 cm^-1 for (Fe,N) Codoped TiO₂. Stretching vibration frequency of (Fe, N) Codoped TiO₂ infrared spectra, Fe and N doped location, molecular structure and bond valence feature are obtained by the principle of electronegativity. Firstly, the reduced mass μ is computed. Then according to the relationship between classical mechanics stretching force constant k and frequency ν, molecular vibration frequency of doped rutile or anatase TiO₂ with the same oxygen octahedron structure unit via combining with the relationship between the force constant and the electrical negative, the calculation of bond order. The results show that the (Fe, N) Codoped TiO₂ infrared spectrum calculated by the principle of electronegativity is in agreement with the stretching vibration frequency by the experimental measurement.

Key words：Electric negative principle；Infrared spectrum；Titania；Doping

收稿日期: 2016-04-13 修订日期: 2016-08-20

中图分类号:

R782.1

基金资助: The National Natural Science Foundation of China(51362017，51262017)，Collaborative innovation center with advanced materials rare metals synergy innovation fund(14051708)

通讯作者: 严继康 E-mail: scyjk@sina.com

作者简介: CHEN Jun-yu，(1994—)，undergraduates, Kunming University of Science and Technology, Institute of Materials Science and Engineering e-mail： 754271418@qq.com

引用本文:

陈俊宇，姜贵民，滕媛，陈东东，严继康，甘国友. (Fe，N)共掺杂TiO₂红外光谱的电负性原理研究[J]. 光谱学与光谱分析, 2017, 37(07): 2305-2310.
CHEN Jun-yu, JIANG Gui-min, TENG Yuan, CHEN Dong-dong, YAN Ji-kang, GAN Guo-you. Research on Infrared Spectra of (Fe, N) Doped TiO₂ by the Electronegativity Principle. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(07): 2305-2310.

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