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

36 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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@article{3442cd7436c7418da8f036ba0e38b897,

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",

month = oct,

day = "2",

doi = "10.1021/jp034872+",

language = "English",

volume = "107",

pages = "10722--10728",

journal = "Journal of Physical Chemistry B",

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publisher = "American Chemical Society",

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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.

UR - https://www.scopus.com/pages/publications/0142072007

U2 - 10.1021/jp034872+

DO - 10.1021/jp034872+

M3 - Article

AN - SCOPUS:0142072007

SN - 1520-6106

VL - 107

SP - 10722

EP - 10728

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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