Effects of microfabrication processing on the electrochemistry of carbon nanofiber electrodes

Timothy E. McKnight; Anatoli V. Melechko; Michael A. Guillorn; Vladimir I. Merkulov; Mitchel J. Doktycz; Christopher T. Culbertson; Stephen C. Jacobson; Douglas H. Lowndes; Michael L. Simpson

doi:10.1021/jp034872+

Effects of microfabrication processing on the electrochemistry of carbon nanofiber electrodes

Timothy E. McKnight, Anatoli V. Melechko, Michael A. Guillorn, Vladimir I. Merkulov, Mitchel J. Doktycz, Christopher T. Culbertson, Stephen C. Jacobson, Douglas H. Lowndes, Michael L. Simpson

Biosciences Division

Research output: Contribution to journal › Article › peer-review

35 Scopus citations

Abstract

We describe the fabrication and electrochemical characterization of as-grown and postprocessed vertically aligned carbon nanofiber forest electrodes at macroscopic (5 mm) and microscopic dimensions (250 μm). We examine the impact of a variety of microfabrication processes that are typically employed during nanofiber-based device synthesis including refractory metal reactive ion etch, oxide coating and removal, and several oxygen-based etch processes-all of which dramatically impact microscale electrode response. We also demonstrate that the high electrochemically active surface area of large scale, macroscopic nanofiber forest electrodes can provide a buffering capacity against surface activation/inactivation. Under diffusion-limited transport conditions, this may preserve the electrochemical response of the electrode during storage and against the impacts of processing techniques used during nanofiber-based device fabrication.

Original language	English
Pages (from-to)	10722-10728
Number of pages	7
Journal	Journal of Physical Chemistry B
Volume	107
Issue number	39
DOIs	https://doi.org/10.1021/jp034872+
State	Published - Oct 2 2003

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title = "Effects of microfabrication processing on the electrochemistry of carbon nanofiber electrodes",

abstract = "We describe the fabrication and electrochemical characterization of as-grown and postprocessed vertically aligned carbon nanofiber forest electrodes at macroscopic (5 mm) and microscopic dimensions (250 μm). We examine the impact of a variety of microfabrication processes that are typically employed during nanofiber-based device synthesis including refractory metal reactive ion etch, oxide coating and removal, and several oxygen-based etch processes-all of which dramatically impact microscale electrode response. We also demonstrate that the high electrochemically active surface area of large scale, macroscopic nanofiber forest electrodes can provide a buffering capacity against surface activation/inactivation. Under diffusion-limited transport conditions, this may preserve the electrochemical response of the electrode during storage and against the impacts of processing techniques used during nanofiber-based device fabrication.",

author = "McKnight, {Timothy E.} and Melechko, {Anatoli V.} and Guillorn, {Michael A.} and Merkulov, {Vladimir I.} and Doktycz, {Mitchel J.} and Culbertson, {Christopher T.} and Jacobson, {Stephen C.} and Lowndes, {Douglas H.} and Simpson, {Michael L.}",

year = "2003",

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doi = "10.1021/jp034872+",

language = "English",

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TY - JOUR

T1 - Effects of microfabrication processing on the electrochemistry of carbon nanofiber electrodes

AU - McKnight, Timothy E.

AU - Melechko, Anatoli V.

AU - Guillorn, Michael A.

AU - Merkulov, Vladimir I.

AU - Doktycz, Mitchel J.

AU - Culbertson, Christopher T.

AU - Jacobson, Stephen C.

AU - Lowndes, Douglas H.

AU - Simpson, Michael L.

PY - 2003/10/2

Y1 - 2003/10/2

N2 - We describe the fabrication and electrochemical characterization of as-grown and postprocessed vertically aligned carbon nanofiber forest electrodes at macroscopic (5 mm) and microscopic dimensions (250 μm). We examine the impact of a variety of microfabrication processes that are typically employed during nanofiber-based device synthesis including refractory metal reactive ion etch, oxide coating and removal, and several oxygen-based etch processes-all of which dramatically impact microscale electrode response. We also demonstrate that the high electrochemically active surface area of large scale, macroscopic nanofiber forest electrodes can provide a buffering capacity against surface activation/inactivation. Under diffusion-limited transport conditions, this may preserve the electrochemical response of the electrode during storage and against the impacts of processing techniques used during nanofiber-based device fabrication.

AB - We describe the fabrication and electrochemical characterization of as-grown and postprocessed vertically aligned carbon nanofiber forest electrodes at macroscopic (5 mm) and microscopic dimensions (250 μm). We examine the impact of a variety of microfabrication processes that are typically employed during nanofiber-based device synthesis including refractory metal reactive ion etch, oxide coating and removal, and several oxygen-based etch processes-all of which dramatically impact microscale electrode response. We also demonstrate that the high electrochemically active surface area of large scale, macroscopic nanofiber forest electrodes can provide a buffering capacity against surface activation/inactivation. Under diffusion-limited transport conditions, this may preserve the electrochemical response of the electrode during storage and against the impacts of processing techniques used during nanofiber-based device fabrication.

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DO - 10.1021/jp034872+

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JO - Journal of Physical Chemistry B

JF - Journal of Physical Chemistry B

IS - 39

ER -

Effects of microfabrication processing on the electrochemistry of carbon nanofiber electrodes

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