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用于甲醛电化学传感器件的一维和二维镍基纳米材料

1-D and 2-D Ni-based nanomaterials for formaldehyde electrochemical sensing devices
课程网址: http://videolectures.net/ipssc2017_trafela_electrochemical_sensin...  
主讲教师: Špela Trafela
开课单位: 约瑟夫·斯特凡研究所
开课时间: 2017-05-23
课程语种: 英语
中文简介:
在本研究中,我们使用KOH修饰的镍电极(薄膜和纳米线)对甲醛(HCHO)进行电氧化,该电极有望用作有效的电化学受体元件。通过从酸性和中性NiSO4基溶液中电沉积,并随后在1M KOH中进行改性,在金衬底上沉积Ni“薄膜”。从SEM结果我们发现,Ni2+溶液的pH值影响沉积膜的形貌。在酸性条件下可形成均匀的镍膜,而在中性条件下可沉积多孔镍膜。采用模板辅助电沉积法在氧化铝模板上制备了直径为200nm、长度为1μm的镍纳米线。在电沉积纳米线之后,在10mNaOH溶液中去除模板以获得独立的纳米线。 由于NiO(OH)/Ni(OH)2氧化还原偶对HCHO具有很高的催化活性,因此KOH改性对HCHO氧化反应的进一步研究具有重要意义。通过一系列电化学测试,研究了改性镍纳米线和镍膜(niooh)对碱性介质中甲醛检测的电催化活性。KOH改性的电位范围必须选择在不形成氧的区域(最大电位0.6V),因为分子氧可以吸附在电极上并抑制HCHO的进一步氧化[1]。 实验结果表明,二维和一维镍基电极(纳米线和薄膜)对于HCHO的氧化显示出显著的电催化活性,并且在1 mM到0.5 M的浓度范围内显示出线性关系。对于1 mM到0.1 M的浓度,在0.5 V左右的电位与Ag/AgCl的电位以及0.8 V左右的电位与Ag/AgCl的电位之间获得了氧化峰。结果表明电氧化反应很可能通过与NiO(OH)的化学反应进行,如图1[2]所示。实验数据进一步显示,与均匀多孔镍电极相比,镍纳米线具有更高的灵敏度(约高7倍),因为曲线电流信号与浓度的斜率达到了更高的值。镍纳米线的检测限为0.1mm,多孔镍膜的检测限为0.4mm,均匀镍膜的检测限为0.5mm。结果表明,镍纳米线具有更高的催化活性,这是因为镍纳米线具有更多的表面活性中心,并且在表面上连接了更多的吸附-OOH基团,从而促进受体元素和HCHO分子之间的电子转移。镍纳米线的这些优点使其有望在实际样品中提供一种低成本和简单的方法。
课程简介: In this study we used KOH-modified Ni electrodes (films and nanowires) for the electro-oxidation of formaldehyde (HCHO), which are promising to be used as effective electrochemical receptor element. Ni ‘’films’’ were deposited on Au substrates by the electro-deposition from acidic and neutral NiSO4-based solutions with subsequent modification in 1 M KOH. From the SEM results we found out that pH of Ni2+ solution affects the morphology of the deposited films. Under acidic conditions homogeneous Ni film was formed, but under neutral conditions porous Ni film was deposited. Ni nanowires (200 nm diameter, 1 μm length) were prepared with template-assisted electrodeposition into alumina templates. After the electrodeposition of the nanowires, the template was removed in 10 M solution of NaOH in order to get free standing wires. The modification step with KOH is very important for the further investigations of HCHO oxidation, because NiO(OH)/Ni(OH)2 redox couple exhibits high catalytic activity towards HCHO. The electrocatalytic activity of modified Ni nanowires and Ni films (Ni-OOH) for formaldehyde detection in alkaline media was investigated via a series of electrochemical measurements. The potential range for modification in KOH has to be chosen in the region where oxygen does not form (the maximum potential 0.6V), because molecular oxygen can be adsorbed on the electrode and inhibits further oxidation of HCHO [1]. Experimental results show that the 2D and 1D Ni-based electrode (nanowires and films) displays a remarked electro-catalytic activity for the oxidation of HCHO and exhibit a linear relationship in a concentration range from 1 mM to 0.5 M. An oxidation peak was obtained at potentials around 0.5 V vs. Ag/AgCl for concentrations 1 mM – 0.1 M and around 0.8 V vs. Ag/AgCl for concentrations above 0.1 M. Results showed that the reaction of the electro-oxidation most probably proceeds by a chemical reaction with NiO(OH) as shown on Scheme 1 [2]. The experimental data further reveal that Ni nanowires exhibits a higher sensitivity (approximately 7x higher) compared to the homogeneous and porous Ni electrode, because the slope of the curve current signals vs. concentrations reached higher value. The detection limit was 0.1 mM for Ni nanowires, 0.4 mM for porous Ni film and 0.5 mM for homogeneous Ni film. It was concluded from results that Ni nanowires exhibit a higher catalytic activity due to the more surface active sites and connected higher amounts of adsorbed –OOH groups on the surface that promote the electron transfer between receptor elements and HCHO molecules. These advantages of Ni nanowires make them promising for providing a low cost and simple method in real samples.
关 键 词: 电化学受体元件; 二维和一维镍基电极; 镍纳米线
课程来源: 视频讲座网
数据采集: 2021-11-27:zkj
最后编审: 2021-11-27:zkj
阅读次数: 56