Compared with a-Fe2O3 and ZnxFe3-XO4 Thin Films Grown by Chemical Spray Pyrolysis

International journal of sensor networks and data communications Pub Date : 2017-07-11 DOI:10.4172/2090-4886.1000152

S. SaritaÅ, Erdal Turgut, M. Kundakçı, B. Gürbulak, M. Yıldırım

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引用次数: 5

Abstract

This work describes hematite (a-Fe2O3) and ZnxFe3-XO4 thin films prepared by Chemical Spray Pyrolysis (CSP) method. CSP method allows an optimal control of stoichiometry and impurity incorporation, hematite films modified with Zn2+ was also prepared. Moreover, the most attracting characteristics of the hematite are its stability in neutral and basic solutions, abundance and band gap energy (2.0–2.2 eV) which permits it to absorb approximately 40% of the incident solar spectrum on earth. Nevertheless, the performance of hematite electrodes for water oxidation is restricted by their poor charge transport properties. Hematite has low conductivity and low charge-carrier mobility. In addition, the photoexcited electron–hole pairs have short life time (~10-12 s), which makes the hole diffusion length to be also short (2–4 nm). The charge transport properties of hematite can be improved by dopping. We demonstrated to increase the conductivity of hematite by dopping it with metal cations with 2+ charges which improved the photocatalytic properties. Doping with metal cations with 2+ charges has also brought good photoelectrochemical results. So we iron oxide and Zn-doped iron oxide compounds have been investigated. The structural, optical and magnetic properties of a-Fe2O3 and ZnxFe3-xO4 compounds have been extensively investigated. XRD, XPS, Raman, FE-SEM and AFM techniques have been used for structural analysis; Absorption technique has been used for optical properties; Hall and Vibrating Sample Magnetometer (VSM) techniques have been used for magnetic properties.

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化学喷雾热解制备a-Fe2O3和ZnxFe3-XO4薄膜的比较

采用化学喷雾热解(CSP)法制备赤铁矿(a-Fe2O3)和ZnxFe3-XO4薄膜。CSP法对化学计量学和杂质掺入进行了优化控制，制备了Zn2+修饰的赤铁矿膜。此外，赤铁矿最吸引人的特点是其在中性和碱性溶液中的稳定性，丰度和带隙能量(2.0-2.2 eV)，使其能够吸收地球上大约40%的入射太阳光谱。然而，赤铁矿水氧化电极的性能受到其较差的电荷传输特性的限制。赤铁矿电导率低，载流子迁移率低。此外，光激发的电子-空穴对具有较短的寿命(~10-12 s)，这使得空穴的扩散长度也较短(2-4 nm)。掺入可以改善赤铁矿的电荷输运性质。我们证明了在赤铁矿中掺入带2+电荷的金属阳离子可以提高赤铁矿的导电性，从而改善赤铁矿的光催化性能。带2+电荷的金属阳离子的掺杂也带来了良好的光电化学效果。因此我们对氧化铁和掺锌氧化铁化合物进行了研究。研究了a-Fe2O3和ZnxFe3-xO4化合物的结构、光学和磁性能。采用XRD、XPS、Raman、FE-SEM、AFM等技术进行了结构分析;吸收技术已用于光学性质的研究;霍尔磁强计和振动样品磁强计(VSM)技术已被用于测量磁性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International journal of sensor networks and data communications

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