Biogenic surfactant mediated facile synthesis of visible light sensitized Zn/Mg co-doped TiO2 nanomaterials – a green approach: evaluation of photocatalytic activity by degradation of Amido Black 10B

IF 4.6 3区 环境科学与生态学 Q2 ENGINEERING, ENVIRONMENTAL
S. Tirukkovalluri, G. Jaishree, G. Divya, M. Chippada, I. M. Raju
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引用次数: 0

Abstract

Visible light-driven Zn and Mg co-doped TiO 2 nanomaterials were synthesized by varying dopant concentrations in presence of biogenic surfactant Sapindus emerginatus (biogenic extract) via the Sol-gel method and have been successfully applicated to the degradation of Amido Black 10B (AB 10B), an exemplary anionic textile azo dye pollutant. This study explored the potent capping properties of biogenic extract surfactant by encapsulating the Zn/Mg co-doped TiO 2 . In a view to assessing the physical and optical properties of the as-synthesized catalysts, various advanced instrumental techniques were adopted. The Transmission Electron Microscopy and Scanning Electron Microscopy analysis show the formation of small particle sizes (6.9 nm) pertaining to biogenic surfactant-assisted Zn/Mg co-doped TiO 2 (ZMT4S2). The substitutional doping of Zn and Mg into the TiO 2 framework by substituting Ti 4+ ion and the encapsulation of surfactant around catalyst was confirmed by Fourier Transform-Infrared Spectroscopy (FTIR) spectral studies. The surface area of the ZMT4S2 was found to be high (195 m 2  g − 1 ) as compared with undoped TiO 2 (74 m 2  g − 1 ) and Zn (1.00 wt%) / Mg (0.25 wt%) co-doped TiO 2 (ZMT4) (132 m 2  g − 1 ). The red shift in the absorbance was observed for all the catalysts analyzed using UV-Vis-Diffuse Reflectance Spectroscopy (UV-Vis-DRS) confirms the ZMT4S2 showing less band gap of 2.1 eV than other catalysts. Further the electrical property of the catalyst was studied using Electrochemical Impedance Spectroscopy. The results obtained from impedance and Mott-Schotky plots show the reduced electrical resistance and electron hole recombination respectively. The sensitivity of the catalyst towards visible light was confirmed by its band gap energy measurement using UV-Vis-DRS. The anatase phase of all the catalysts was confirmed using powder X-ray diffraction. The composition and wt% of dopants revealed the Energy Dispersive X-ray spectra agree well with the calculated value. The slightly shifted frequency bands (FTIR) further confirmed the doping of Zn and Mg. The characterization analysis reports further accounts for the effective degradation of AB 10B dye (99%) taking place within 20 min of irradiation time at optimized reaction parameters such as best dopant concentration ZMT4, catalyst dosage (100 mg L − 1 ), dye concentration (10 mg L − 1 ) and solution pH 3.
生物源表面活性剂介导的可见光敏化Zn/Mg共掺杂TiO2纳米材料的快速合成——一种绿色途径:通过降解氨基黑10B评价光催化活性
采用溶胶-凝胶法制备了不同掺杂浓度的可见光驱动Zn和Mg共掺杂二氧化钛纳米材料,并成功用于降解阴离子型纺织偶氮染料污染物Amido Black 10B (AB 10B)。本研究通过包封Zn/Mg共掺杂二氧化钛,探索了生物萃取表面活性剂的有效封盖特性。为了评估合成催化剂的物理和光学性质,采用了各种先进的仪器技术。透射电镜和扫描电镜分析表明,生物源表面活性剂辅助Zn/Mg共掺杂tio2 (ZMT4S2)形成了小颗粒尺寸(6.9 nm)。傅里叶变换-红外光谱(FTIR)研究证实了Zn和Mg通过取代ti4 +离子进入tio2骨架,并在催化剂周围包封了表面活性剂。ZMT4S2的表面积(195 m²g−1)高于未掺杂tio2 (74 m²g−1)和Zn (1.00 wt%) / Mg (0.25 wt%)共掺杂tio2 (ZMT4) (132 m²g−1)。利用uv - vis -漫反射光谱(UV-Vis-DRS)分析了所有催化剂的吸光度红移,证实了ZMT4S2比其他催化剂具有更小的2.1 eV带隙。进一步用电化学阻抗谱法研究了催化剂的电学性能。阻抗图和Mott-Schotky图分别显示了电阻和电子空穴复合的减小。利用UV-Vis-DRS对催化剂的带隙能进行测量,证实了催化剂对可见光的敏感性。用粉末x射线衍射证实了所有催化剂的锐钛矿相。结果表明,掺杂剂的组成和wt%与计算值吻合较好。微移频带(FTIR)进一步证实了Zn和Mg的掺杂。表征分析报告进一步说明了在最佳掺杂剂浓度ZMT4、催化剂用量(100 mg L−1)、染料浓度(10 mg L−1)和溶液pH 3等优化反应参数下,ab10b染料在20 min内有效降解(99%)。
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来源期刊
CiteScore
8.00
自引率
2.00%
发文量
47
审稿时长
30 weeks
期刊介绍: The primary goal of Sustainable Environment Research (SER) is to publish high quality research articles associated with sustainable environmental science and technology and to contribute to improving environmental practice. The scope of SER includes issues of environmental science, technology, management and related fields, especially in response to sustainable water, energy and other natural resources. Potential topics include, but are not limited to: 1. Water and Wastewater • Biological processes • Physical and chemical processes • Watershed management • Advanced and innovative treatment 2. Soil and Groundwater Pollution • Contaminant fate and transport processes • Contaminant site investigation technology • Soil and groundwater remediation technology • Risk assessment in contaminant sites 3. Air Pollution and Climate Change • Ambient air quality management • Greenhouse gases control • Gaseous and particulate pollution control • Indoor air quality management and control 4. Waste Management • Waste reduction and minimization • Recourse recovery and conservation • Solid waste treatment technology and disposal 5. Energy and Resources • Sustainable energy • Local, regional and global sustainability • Environmental management system • Life-cycle assessment • Environmental policy instruments
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