基于三维纳米银修饰电极的硝酸根微型传感芯片研究

doi:10.6023/A1110013

化学学报 ›› 2012, Vol. 70 ›› Issue (03): 291-296.DOI: 10.6023/A1110013 上一篇下一篇

研究论文

基于三维纳米银修饰电极的硝酸根微型传感芯片研究

胡敬芳^a,b, 孙楫舟^a, 边超^a, 佟建华^a, 李洋^a,b, 夏善红^a

a 中国科学院电子学研究所传感技术国家重点实验室北京 100080;
b 中国科学院研究生院北京 100080

投稿日期:2011-10-28 修回日期:2011-11-18 发布日期:2011-11-30
通讯作者: 夏善红 E-mail:shxia@mail.ie.ac.cn
基金资助:
国家重点基础研究发展计划(973 计划, No. 2009CB320300)、国家水体污染控制与治理科技重大专项课题(No. 2009ZX07527-007)和国家自然科学基金(No. 60971070)资助项目.

Study on Micro-sensing Chip of Nitrate Based on Three-dimensional Nano-structured Silver Modified Electrode

Hu Jingfang^a,b, Sun Jizhou^a, Bian Chao^a, Tong Jianhuaa^a, Li Yang^a,b, Xia Shanhong^a

a State Key Laboratory of Transducer Technology, Institute of Electronics/Chinese Academy of Sciences, Beijing 100080;
b Graduate University of Chinese Academy of Sciences/Beijing 100080

Received:2011-10-28 Revised:2011-11-18 Published:2011-11-30
Supported by:
National Basic Research Program of China (973 Program) (No. 2009CB320300), National Water Pollution Control and Management Technology Major Projects (No. 2009ZX07527-007) and the National Natural Science Foundation Program of China (No. 60971070).

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摘要/Abstract

研制一种基于金叉指微电极阵列(IDA)的电流型硝酸根离子(NO₃^-)微传感电极芯片. 基于微机电系统(Micro-Electro-Mechanical Systems, MEMS)工艺制备金IDA 微电极, 通过电化学沉积技术在IDA 微电极表面修饰三维枝状结构纳米银敏感膜, 利用敏感膜对硝酸根离子良好的电催化还原性能, 采用脉冲方波伏安(SWV)电化学测量方法,实现对硝酸根离子在25～1000 μmol/L 浓度范围内的快速检测, 灵敏度达9.5 nA/(μmol/L), 线性度为99.98%, 检测下限为10 μmol/L. 考察水体中常见的NO₂^- , F^-, PO₄^3- , SO₄^2- , CO₃^2-, NH₄⁺ , Na⁺和K⁺等离子对该传感芯片的干扰性能,传感芯片表现出较好的抗干扰性能. 制备的三维枝状结构纳米银修饰IDA微电极可实现水环境(pH 5.0～9.0)中NO₃^- 的电化学检测, 对应用于自然水环境中硝酸根离子的现场检测具有积极意义.

关键词: 三维枝状纳米结构敏感膜, 叉指微电极阵列, 自然水环境, 硝酸根检测

A new type of micro amperometric sensing chip based on gold interdigitated microband array (IDA) electrode for trace nitrate determination was developed in this paper. The IDA as working electrode was fabricated with micro-electro-mechanical systems (MEMS) technology. Three-dimensional (3D) nano-structured dendritic silver was electrochemically deposited on the IDA electrode surface, which showed superior electrocatalytic reduction of nitrate than silver nanoparticle modified IDA and regular silver wire electrode. The experiment results demonstrated that the proposed chip showed high sensitivity (9.5 nA/(μmol/L), within a concentration range of 25～1000 μmol/L (R²＝0.9998) and low detection limit (10 μmol/L) using square-wave voltammetry method. Interference analysis with 8 kinds of ions ( NO₂^-, F^-, PO₄^3- , SO₄^2- , CO₃^2- , NH₄⁺ , Na⁺and K⁺) commonly found in surface water indicated that the microchips in this paper had good selectivity to NO₃^- . It was noteworthy that the 3D nano-structured dendritic silver as sensing film modified on IDA electrode could electrochemically reduce nitrate at a pH range of 5.0～9.0 which is important for further study of field and real-time monitoring nitrate ions in natural water.

Key words: three-dimensional (3D) nano-structured silver, interdigitated microband array (IDA) electrode, natural water environment, nitrate determination

引用此文

胡敬芳, 孙楫舟, 边超, 佟建华, 李洋, 夏善红. 基于三维纳米银修饰电极的硝酸根微型传感芯片研究[J]. 化学学报, 2012, 70(03): 291-296.

Hu Jingfang, Sun Jizhou, Bian Chao, Tong Jianhuaa, Li Yang, Xia Shanhong. Study on Micro-sensing Chip of Nitrate Based on Three-dimensional Nano-structured Silver Modified Electrode[J]. Acta Chimica Sinica, 2012, 70(03): 291-296.

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基于三维纳米银修饰电极的硝酸根微型传感芯片研究

Study on Micro-sensing Chip of Nitrate Based on Three-dimensional Nano-structured Silver Modified Electrode

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