Thin film electrode: a new method for the fabrication of submicrometer band electrodes

Seddon, Brian; Eddowes, M.J.; Firth, Adam; Owen, A.E.

doi:10.1016/0013-4686(91)85272-9

Cited by 21 publications

(20 citation statements)

References 26 publications

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“…Paired microbands have been developed by an epoxied thin mica sheet with sputtered gold on both sides [11] or by sealing of two metalized glass slides separated with a plastic spacer [12] . Photolithography has also been employed to fabricate microbands [13][14][15] and interdigited array electrodes [16] by metal evaporation [17] , sputtering [18,19] and chemical vapour deposition [7,20,21] . Boron doped diamond ultramicroband electrodes have been realised based on lithography and chemical vapour deposition [22,23] .…”

Section: Introductionmentioning

confidence: 99%

Arrays of Screen‐Printed Graphite Microband Electrodes as a Versatile Electroanalysis Platform

et al. 2014

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Arrays of microband electrodes were developed by screen printing followed by cutting, which enabled the realization of microband arrays at the cut edge. Microband arrays of different designs were characterised with physical and electrochemical methods. In both cases the methods showed that the microband width was around 5 m. Semi-steady-state cyclic voltammetry responses were observed for redox probes.Chronocoulometric measurements showed the establishment of convergent diffusion regimes characterized by current densities similar to those of a single microelectrode.The analytical performance of the elaborated electrode system and its versatility were illustrated with two electrochemical assays: detection of ascorbic acid via direct oxidation and a mediated glucose biosensor fabricated via dip coating. Due to convergent mass transport both systems showed enhancement of the analytical characteristics. The developed approach can be adapted to automated electrode recovery.

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Section: Introductionmentioning

confidence: 99%

Arrays of Screen‐Printed Graphite Microband Electrodes as a Versatile Electroanalysis Platform

et al. 2014

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“…As can be seen in Figure 3, the theoretical limiting current (5.35 mA) is in good accordance with the experimental value (5.27 mA). On the other hand, in the case of a hemicylindrical diffusion, the theoretical limiting current of a microband array is given by [16]: where l is the microband length, m is the number of the bands of the array, and y ¼ DtW 2 =p 2 (where W corresponds to the band width and t is the time constant (RT=Fn); n is the scan rate). For the C565000 arrays, a comparison between the experimental data and the corresponding theoretical curve shows a very good accordance for scan rates lower than 100 mV s À1 .…”

Section: Resultsmentioning

confidence: 99%

“…In sum, for band geometries, our results show that as the aspect ratio (length=width) increases, the diffusion profiles tend to become predominantly hemicylindrical, while their radial diffusion components diminishes. The presence of radial diffusion in the microband geometry can be attributed to the edge effect at the extremity of the bands [16].…”

Section: Resultsmentioning

confidence: 99%

“…These microfabrication techniques offer unique advantages to explore new microelectrode geometries (i.e., microbands rather than the most commonly investigated microdisks) and experimentally investigate the microelectrode geometry-analytical performance relationship. Moreover, the Hg electroplating onto microelectrodes with a high aspect ratio band geometry is still challenging [16][17][18][19], in comparison with the disk geometry which is more compatible with the natural tendency of Hg to form spherical microdrops. On the other hand, it is worth noting that the total stripping current produced by the array is proportional to the number of the microelectrodes and the steady-state diffusion behavior is preserved provided that the microelectrodes are sufficiently distanced from each other to avoid overlapping of the diffusion layer [20].…”

Section: Introductionmentioning

confidence: 99%

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Effect of the Microelectrode Geometry on the Diffusion Behavior and the Electroanalytical Performance of Hg-Electroplated Iridium Microelectrode Arrays Intended for the Detection of Heavy Metal Traces

et al. 2001

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“…Therefore, nanoband electrodes have many advantages of other nanoelectrodes in addition to a relatively high electrochemical response, and a simple and inexpensive fabrication process. The band electrodes with widths o1 mm can be simply constructed by using conductor foils and/or metal vapor deposition [13,[33][34][35][36]. Because of the macroscopic length and nanosized width, when a nanoband electrode detector is used in microchip, it can scan the whole width of the microchannel like a microelectrode detector and perform as a nanoelectrode detector for ECD in the longitudinal direction.…”

Section: Introductionmentioning

confidence: 99%

Nanoband electrode for high‐performance in‐channel amperometric detection in dual‐channel microchip capillary electrophoresis

2011

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A nanoband electrode detector integrated with a dual-channel polydimethylsiloxane microchip is proposed for in-channel amperometric detection in microchip capillary electrophoresis. Gold nanoband electrodes, which were fabricated on SU-8 substrates with a 100-nm-width gold layer, were introduced into the dual-channel microchip to be an electrochemical detector. Due to the nano-sized width of the detector, the noise of the amperometric detection was significantly reduced, and a high separation resolution was achieved for monitoring the analytes. The detection sensitivity of the system was improved by high signal-to-noise ratio, and a low detection limit on microchip was obtained for p-aminophenol (2.09 nM). Because of the high resolution in measuring half-peak width, the plate number that is used to evaluate the separation efficiency was 1.5-fold higher than that using 50-μm-width electrochemical detector. The effect of sample injection time and data acquisition time on separation efficiency was investigated, and an attractive separation efficiency was achieved with a plate number up to 17,500.

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Thin film electrode: a new method for the fabrication of submicrometer band electrodes

Cited by 21 publications

References 26 publications

Arrays of Screen‐Printed Graphite Microband Electrodes as a Versatile Electroanalysis Platform

Arrays of Screen‐Printed Graphite Microband Electrodes as a Versatile Electroanalysis Platform

Effect of the Microelectrode Geometry on the Diffusion Behavior and the Electroanalytical Performance of Hg-Electroplated Iridium Microelectrode Arrays Intended for the Detection of Heavy Metal Traces

Nanoband electrode for high‐performance in‐channel amperometric detection in dual‐channel microchip capillary electrophoresis

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