Structural, dielectric properties and electrical conductivity of highly efficient photocatalytic TiO2@ZrO2 system

IF 2.4 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Solid State Communications Pub Date : 2025-09-22 DOI:10.1016/j.ssc.2025.116165

Anis Fkiri , Aymen Selmi , Mohamed Ali Saidani , Tariq Altalhi , Amine Mezni

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引用次数: 0

Abstract

In this work, binary TiO₂@ZrO₂ hybrid nanotubes was prepared using a fast efficient solvothermal procedure. The solvent used in this reaction is 1.3-propandiol reacted as both solvent, oxidant and surfactant agent. The obtained binary TiO₂@ZrO₂ hybrid nanotubes was then fully characterized to evaluate the microstructure, size and shape using XRD diffraction technique, TEM microscopy and XPS spectrometry. The photocatalytic activity, evaluated via methyl orange degradation under UV irradiation, showed a remarkable 94.6 % efficiency and excellent recyclability. In addition to their photocatalytic performance, the materials exhibit interesting electrical properties. After that, the microwave dielectric properties of binary TiO₂@ZrO₂ hybrid nanotubes were investigated over the range of frequency between 100 Hz and 1 MHz and in the temperature range of 20 °C-300 °C. The AC conductivity is insured by a process defined as a hopping transport mechanism. The Nyquist plots show the dominance of the bulk effect in the compound. Electrical phenomena in the material can appropriately be modeled in terms of an equivalent circuit with R and CPE in parallel. The fitting procedure used here allows us to determine the value of R and parameters of CPE with good precision. At temperatures above 100 °C the equivalent circuit model shows the appearance of an additional Constant Phase Element (CPE2) in equivalent circuit which can be related to the dielectric relaxation processes associated with the migration of oxygen vacancies or ions such as Ti⁴⁺ and/or Zr⁴⁺. This ionic migration could be responsible for the dielectric relaxation observed at low frequencies and could also explain the large decrease in permittivity in this frequency range.

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高效光催化TiO2@ZrO2体系的结构、介电性能和电导率

本文采用快速高效的溶剂热法制备了二元TiO2@ZrO2杂化纳米管。本反应所用溶剂为1.3-丙二醇，同时作为溶剂、氧化剂和表面活性剂。然后利用XRD衍射技术、TEM显微镜和XPS光谱对所得的二元TiO2@ZrO2杂化纳米管的微观结构、尺寸和形状进行了全面表征。通过甲基橙在紫外照射下的降解评价，其光催化活性达到了94.6%，可回收性好。除了光催化性能外，这些材料还表现出有趣的电学性质。然后，在频率为100 Hz ~ 1 MHz、温度为20℃~ 300℃范围内，研究了二元TiO2@ZrO2杂化纳米管的微波介电性能。交流电导率是通过一个定义为跳跃传输机制的过程来保证的。奈奎斯特图显示了体效应在化合物中占主导地位。材料中的电现象可以适当地用R和CPE并联的等效电路来模拟。这里使用的拟合程序使我们能够以较好的精度确定R的值和CPE的参数。在高于100°C的温度下，等效电路模型显示等效电路中出现了额外的恒相元件（CPE2），这可能与氧空位或离子（如Ti4+和/或Zr4+）迁移相关的介电松弛过程有关。这种离子迁移可能是在低频观察到的介电松弛的原因，也可以解释在这个频率范围内介电常数的大幅下降。

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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来源期刊

Solid State Communications 物理-物理：凝聚态物理

CiteScore

3.40

自引率

4.80%

发文量

287

审稿时长

51 days

期刊介绍： Solid State Communications is an international medium for the publication of short communications and original research articles on significant developments in condensed matter science, giving scientists immediate access to important, recently completed work. The journal publishes original experimental and theoretical research on the physical and chemical properties of solids and other condensed systems and also on their preparation. The submission of manuscripts reporting research on the basic physics of materials science and devices, as well as of state-of-the-art microstructures and nanostructures, is encouraged. A coherent quantitative treatment emphasizing new physics is expected rather than a simple accumulation of experimental data. Consistent with these aims, the short communications should be kept concise and short, usually not longer than six printed pages. The number of figures and tables should also be kept to a minimum. Solid State Communications now also welcomes original research articles without length restrictions. The Fast-Track section of Solid State Communications is the venue for very rapid publication of short communications on significant developments in condensed matter science. The goal is to offer the broad condensed matter community quick and immediate access to publish recently completed papers in research areas that are rapidly evolving and in which there are developments with great potential impact.