沉积工艺对聚苯胺涂层电学性能的影响及其抗磨损性能
收稿日期: 2019-03-14
网络出版日期: 2020-08-18
基金资助
国家自然科学基金资助项目(51675330)
Effect of Deposition Process on Electrical Properties of Polyaniline Coating and Its Wear Resistance
Received date: 2019-03-14
Online published: 2020-08-18
神经电极表面涂层对电极性能有重要影响,其中沉积工艺是重要的影响参量.本文着重考察涂层沉积工艺对其电学性能的影响,并对最佳沉积工艺所得涂层的抗磨损性能进行研究.具体而言,在控制沉积过程中电极通过电荷量相当的前提下,比较3种聚苯胺电化学沉积方法的优劣.结果显示:相比裸电极,循环伏安沉积电极阻抗降低了29.7%,CV面积增加了4.05倍;恒电流沉积电极阻抗降低了39.8%,CV面积增加了5.4倍;恒电位沉积电极阻抗降低了4.3%,CV面积增加了4.9倍,恒电流法效果最佳.较低的阻抗及较大的CV面积意味着较好的电学性能.在此标准下,恒电流沉积时间为600~700s时,沉积效果较好.为考察聚苯胺涂层磨损后对电极性能改善效果的影响,设计了一种模拟体内磨损装置进行相关试验.结果显示:磨损过程中涂层的电学性能改善效果逐渐下降,经4 h磨损后,修饰电极的阻抗值甚至高于裸电极阻抗.因此,在对导电涂层的评估中,其抗磨损性能应引起重视.
李伟, 张文光, 于谦, 谢颉 . 沉积工艺对聚苯胺涂层电学性能的影响及其抗磨损性能[J]. 上海交通大学学报, 2020 , 54(8) : 778 -784 . DOI: 10.16183/j.cnki.jsjtu.2019.072
The surface coating of the nerve electrode has an important influence on the performance of the electrode, and the deposition process is an important influencing parameter. This paper focuses on the effect of coating deposition process on its electrical properties, and studies the wear resistance of the coating obtained by the best deposition process. Specifically, the advantages and disadvantages of the three polyaniline electrochemical deposition methods are compared under the premise of controlling the amount of charge passing through the electrodes during the deposition process. The results show that compared with the bare electrode, the impedance of the cyclic voltammetric deposition electrode decreases by 29.7% and the CV area increases by 4.05 times. The impedance of the constant current deposition electrode decreases by 39.8%, and the CV area increases by 5.4 times. The impedance of the constant potential deposition electrode decreases by 4.3% and CV area increases by 4.9 times. The constant current method works best. A lower impedance and larger CV area mean a better electrical performance. Under this standard, deposition is better while the deposition time of constant current is between 600 and 700 s. In order to investigate the effect of polyaniline coating on the performance improvement of the electrode after wear, this paper has designed a simulated internal wear device for related experiments. The results show that the electrical properties of the coating are gradually reduced during the wear process. After 4h of wear, the impedance of the modified electrode is even higher than that of the bare electrode. Therefore, the anti-wear properties of the coating should be taken into account in the evaluation of conductive coatings.
Key words: polyaniline; deposition method; deposition parameters; wear
| [1] | KOZAI T D Y, CATT K, LI X, et al. Mechanical failure modes of chronically implanted planar silicon-based neural probes for laminar recording[J]. Biomaterials, 2015,37(1):25-39. |
| [2] | BARRESE J C, RAO N, PAROO K, et al. Failure mode analysis of silicon-based intracortical microelectrode arrays in non-human primates[J]. Journal of Neural Engineering, 2013,10(6):066014. |
| [3] | SAXENA T, KARUMBAIAH L, GAUPP E A. The impact of chronic blood-brain barrier breach on intracortical elertrode function[J]. Biomatrials, 2013,34:4703-4713. |
| [4] | PRASAD A, XUE Q S, DIEME R, et al. Abiotic-biotic characterization of Pt/Ir microelectrode arrays in chronic implants[J]. Frontiers in Neuroengineering, 2014,7(2):1-15. |
| [5] | PRASAD A, XUE Q S, SANKAR V, et al. Comprehensive characterization and failure modes of tungsten microwire arrays in chronic neural implants[J]. Journal of Neural Engineering, 2012,9(5):056015. |
| [6] | LOGOTHETIS N K, AUGATH M, MURAYAMA Y, et al. The effects of electrical microstimulation on cortical signal propagation[J]. Nature Neuroscience, 2010,13(10):1283-1291. |
| [7] | ZHANG H, ZHU Z H, WU L. Intergration of conducting polymer with flexible thin coating micro electrode arrays for improved neural interfaces[J]. Journal of Functionalmater IaIs And Devices, 2010,16(5):457-466. |
| [8] | CHEN N, TIAN L L, PATIL A C, et al. Neural interfaces engineered via micro-and nanostructured coatings[J]. Nano Today, 2017,14(3):59-83. |
| [9] | POPPENDIECK W, HOFFMANN K P. Coating of neural microelectrodes with intrinsically conducting polymers as a means to improve their electrochemical properties[C]// 4th European Conference of the International Federation for Medical and Biological Engineering. Berlin Heidelberg: Springer, 2009: 2409-2412. |
| [10] | GILLETTI A, MUTHUSWAMY J. Brain micromotion around implants in the rodent somatosensory cortex[J]. Journal of Neural Engineering, 2006,3(3):189-195. |
| [11] | LI M, YAN Y, WANG Q, et al. A simulation of current focusing and steering with penetrating optic nerve electrodes[J]. Journal of Neural Engineering, 2013,10(6):066007. |
| [12] | 张文光, 吴栋栋, 李正伟, 等. 聚苯胺-二氧化锰涂层的电化学合成及其对神经微电极界面性能的影响[J]. 上海交通大学学报, 2014,48(2):199-204. |
| [12] | ZHANG Wenguang, WU Dongdong, LI Zhengwei, et al. Electrochemically synthesized PANI-MnO2 coatings and their effect on interface properties of neural microelectrode[J]. Journal of Shanghai Jiao Tong University, 2014,48(2):199-204. |
| [13] | 吴栋栋. 聚苯胺复合材料涂层的合成及其对神经电极界面性能的影响[D]. 上海交通大学, 2014. |
| [13] | WU Dongdong. Synthesis of polyaniline composite coatings and its effect on the interface properties of neural electrodes[D]. Shanghai Jiao Tong University, 2014. |
| [14] | COGAN S F. Neural stimulation and recording electrodes[J]. Annual Review of Biomedical Engineering, 2008,10(1):275-309. |
| [15] | 李剑, 张智贤, 姚素薇, 等. 恒电位法制备聚苯胺薄膜及其表征[C]// 2009年全国电子电镀及表面处理学术交流会论文集.上海: 上海市电子学会电子电镀专业委员会, 2009: 429-432. |
| [15] | LI Jian, ZHANG Zhixian, YAO Suwei, et al. Preparation and characterization of polyaniline film by potentiostatic method[ C]//Proceedings of the 2009 National Electroplating and Surface Treatment Academic Exchange Conference. Shanghai: Electronic Plating Committee of Shanghai Institute of Electronics 2009: 429-432. |
| [16] | HE Z, PEI W H, ZHAO S S, et al. Fabrication of iridium oxide neural electrodes at the wafer level[J]. Science China Technological Sciences, 2016,59(9):1399-1406. |
| [17] | JAIN A, KIM Y T, MCKEON R J, et al. In situ gelling hydrogels for conformal repair of spinal cord defects, and local delivery of BDNF after spinal cord injury[J]. Biomaterials, 2006,27(3):497-504. |
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