Electrochemical characterization of parylene-embedded carbon nanotube nanoelectrode arrays

Miserendino, Scott; Yoo, Juhwan; Cassell, Alan M.; Tai, Yu‐Chong

doi:10.1088/0957-4484/17/4/005

Cited by 27 publications

(23 citation statements)

References 9 publications

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“…Anodic I pa and cathodic I pc peak currents were taken from the linear fit of the voltammogram where no electrochemical analyte activity was observed [16,17]. The electroactive area (A) was obtained from the slope of the cathodic peak (I pc ) versus the square root of the scan rate ( ffiffi ffi v p ) at a K 4 Fe(CN) 6 concentration of 5 mM referring to the previous mentioned expression (Eq.…”

Section: Electrochemical Measuresmentioning

confidence: 99%

“…In addition, considering once again the Randles-Sevcik equation, the sensitivity (S) and detection limit were computed since these are two important parameters in sensing applications. The sensitivity per electrode area was evaluated from the angular coefficient of the straight line obtained by plotting current density values versus the K 4 Fe(CN) 6 concentration [4,17]. To evaluate this parameter, we varied the target concentration from 0 to 25 mM by steps of 5 mM at a scan rate of 100 mV/s.…”

Section: Electrochemical Measuresmentioning

confidence: 99%

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Comparison of two different carbon nanotube-based surfaces with respect to potassium ferricyanide electrochemistry

et al. 2012

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This paper describes the electrochemical investigation of two multi-walled carbon nanotube-based electrodes using potassium ferricyanide as a benchmark redox system. Carbon nanotubes were fabricated by chemical vapor deposition on silicon wafer with camphor and ferrocene as precursors. Vertically-aligned as well as islands of horizontally-randomly-oriented carbon nanotubes were obtained by varying the growth parameters. Cyclic voltammetry was the employed method for this electrochemical study. Vertical nanotubes showed a slightly higher kinetic. Regarding the sensing parameters we found a sensitivity for vertical nanotubes almost equal to the sensitivity obtained with horizontally/randomly oriented nanotubes (71.5 ± 0.3 μA/(mM cm 2 ) and 62.8± 0.3 μA/(mM cm 2 ), respectively). In addition, values of detection limit are of the same order of magnitude. Although tip contribution to electron emission has been shown to be greatly larger than the lateral contribution on single carbon nanotubes per unit area, the new findings reported in this paper demonstrate that the global effects of nanotube surface on potassium ferricyanide electrochemistry are comparable for these two types of nanostructured surfaces.

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Section: Electrochemical Measuresmentioning

confidence: 99%

Section: Electrochemical Measuresmentioning

confidence: 99%

Comparison of two different carbon nanotube-based surfaces with respect to potassium ferricyanide electrochemistry

et al. 2012

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“…The cathodic peak currents (I pc ) were taken from the baseline of the voltammogram [17,18]. The baseline current was determined by a linear fit of the voltammogram where no electrochemical analyte activity was observed.…”

Section: Electrochemical Apparatusmentioning

confidence: 99%

“…The baseline current was determined by a linear fit of the voltammogram where no electrochemical analyte activity was observed. For a reversible reaction at standard temperature the expected peak current, I p , can be computed referring to the Randles-Sevcik equation [17,18] …”

Section: Electrochemical Apparatusmentioning

confidence: 99%

Comparing sensitivities of differently oriented multi-walled carbon nanotubes integrated on silicon wafer for electrochemical biosensors

Taurino¹,

Carrara²,

Giorcelli³

et al. 2011

Sensors and Actuators B: Chemical

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a b s t r a c tIn this study, we report on multi-walled carbon nanotubes fabricated on silicon substrate with four different orientations via chemical vapor deposition. It is well-known that chemical treatments improve the nanotube electrochemical reactivity by creating edge-like defects on their exposed sidewalls. Before use, we performed an acid treatment on carbon nanotubes. To prove the effect of the treatment on these nanostructured electrodes, contact angles were measured. Then, sensitivities and detection limits were evaluated performing cyclic voltammetry. Two target molecules were used: potassium ferricyanide, an inorganic electroactive molecule, and hydrogen peroxide that is a product of reactions catalyzed by many enzymes, such as oxidases and peroxidases. Carbon nanotubes with tilted tips become hydrophilic after the treatment showing a contact angle of 22 • ± 2 • . This kind of electrode has shown also the best electrochemical performance. Sensitivity and detection limit values are 110.0 ± 0.5 A/(mM cm 2 ) and 8 M for potassium ferricyanide solutions and 16.4 ± 0.1 A/(mM cm 2 ) and 24 M using hydrogen peroxide as target compound. Considering the results of wettability and voltammetric measurements, nanotubes with tilted tips-based electrodes are found to be the most promising for future biosensing applications.Crown

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“…Parylene-C (p-xylene) was chosen as the material for the flexible substrate because of its excellent chemical resistance and its ability to coat samples with high levels of uniformity and penetration. Other groups mention coating nanotubes with parylene-c for the purpose of nanotube protection, but have not attempted a transfer onto a parylene substrate [13][14]. We placed the device to be coated inside a PDS 2010 Parylene coater and deposited 19 grams of parylene throughout the chamber, resulting in an actual coating thickness of 25 µ m. Using standard microfabrication techniques, release of the SWCNT-parylene system was accomplished by wet etching the silicon substrate.…”

Section: Device Transfermentioning

confidence: 99%

Strain-Based Electrical Properties of Systems of Carbon Nanotubes Embedded in Parylene

et al. 2006

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We have fabricated flexible electronic devices to test the strain-based change in resistance of a network of single-walled carbon nanotubes (SWCNTs) for use in microscale, high resolution magnetometry. To do this, we first develop a simple, reliable method to obtain catalyst nanoparticles for carbon nanotube growth through indirect, thin-film evaporation. Next we fabricate a two-terminal SWCNT device on a rigid substrate. We then transfer the device, intact, to a flexible substrate for strain testing. Herein, we report progress in growth and measurement techniques.

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Electrochemical characterization of parylene-embedded carbon nanotube nanoelectrode arrays

Cited by 27 publications

References 9 publications

Comparison of two different carbon nanotube-based surfaces with respect to potassium ferricyanide electrochemistry

Comparison of two different carbon nanotube-based surfaces with respect to potassium ferricyanide electrochemistry

Comparing sensitivities of differently oriented multi-walled carbon nanotubes integrated on silicon wafer for electrochemical biosensors

Strain-Based Electrical Properties of Systems of Carbon Nanotubes Embedded in Parylene

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