An investigation into the feasibility of myoglobin-based single-electron transistors

Debin Li; Peter M. Gannett; David Lederman

doi:10.1088/0957-4484/23/39/395705

An investigation into the feasibility of myoglobin-based single-electron transistors

Debin Li
, Peter M. Gannett
, David Lederman

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

13 Scopus citations

Abstract

Myoglobin single-electron transistors were investigated using nanometer-gap platinum electrodes fabricated by electromigration at cryogenic temperatures. Apomyoglobin (myoglobin without the heme group) was used as a reference. The results suggest single-electron transport is mediated by resonant tunneling with the electronic and vibrational levels of the heme group in a single protein. They also represent a proof-of-principle that proteins with redox centers across nanometer-gap electrodes can be utilized to fabricate single-electron transistors. The protein orientation and conformation may significantly affect the conductance of these devices. Future improvements in device reproducibility and yield will require control of these factors.

Original language	English
Article number	395705
Journal	Nanotechnology
Volume	23
Issue number	39
DOIs	https://doi.org/10.1088/0957-4484/23/39/395705
State	Published - Oct 5 2012
Externally published	Yes

ASJC Scopus Subject Areas

Bioengineering
General Chemistry
General Materials Science
Mechanics of Materials
Mechanical Engineering
Electrical and Electronic Engineering

Keywords

Animals
Apoproteins/chemistry
Electric Conductivity
Electrons
Feasibility Studies
Heme/chemistry
Horses
Myoglobin/chemistry
Nanotechnology/instrumentation
Platinum/chemistry
Reproducibility of Results
Transistors, Electronic

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10.1088/0957-4484/23/39/395705

Cite this

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title = "An investigation into the feasibility of myoglobin-based single-electron transistors",

abstract = "Myoglobin single-electron transistors were investigated using nanometer-gap platinum electrodes fabricated by electromigration at cryogenic temperatures. Apomyoglobin (myoglobin without the heme group) was used as a reference. The results suggest single-electron transport is mediated by resonant tunneling with the electronic and vibrational levels of the heme group in a single protein. They also represent a proof-of-principle that proteins with redox centers across nanometer-gap electrodes can be utilized to fabricate single-electron transistors. The protein orientation and conformation may significantly affect the conductance of these devices. Future improvements in device reproducibility and yield will require control of these factors. ",

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doi = "10.1088/0957-4484/23/39/395705",

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AU - Gannett, Peter M.

AU - Lederman, David

PY - 2012/10/5

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N2 - Myoglobin single-electron transistors were investigated using nanometer-gap platinum electrodes fabricated by electromigration at cryogenic temperatures. Apomyoglobin (myoglobin without the heme group) was used as a reference. The results suggest single-electron transport is mediated by resonant tunneling with the electronic and vibrational levels of the heme group in a single protein. They also represent a proof-of-principle that proteins with redox centers across nanometer-gap electrodes can be utilized to fabricate single-electron transistors. The protein orientation and conformation may significantly affect the conductance of these devices. Future improvements in device reproducibility and yield will require control of these factors.

AB - Myoglobin single-electron transistors were investigated using nanometer-gap platinum electrodes fabricated by electromigration at cryogenic temperatures. Apomyoglobin (myoglobin without the heme group) was used as a reference. The results suggest single-electron transport is mediated by resonant tunneling with the electronic and vibrational levels of the heme group in a single protein. They also represent a proof-of-principle that proteins with redox centers across nanometer-gap electrodes can be utilized to fabricate single-electron transistors. The protein orientation and conformation may significantly affect the conductance of these devices. Future improvements in device reproducibility and yield will require control of these factors.

KW - Animals

KW - Apoproteins/chemistry

KW - Electric Conductivity

KW - Electrons

KW - Feasibility Studies

KW - Heme/chemistry

KW - Horses

KW - Myoglobin/chemistry

KW - Nanotechnology/instrumentation

KW - Platinum/chemistry

KW - Reproducibility of Results

KW - Transistors, Electronic

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JO - Nanotechnology

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ER -

An investigation into the feasibility of myoglobin-based single-electron transistors

Abstract

ASJC Scopus Subject Areas

Keywords

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