Structured Graphene Devices for Mass Transport

A Barreiro Megino; R Rurali; ER Hernandez; A Bachtold

Structured Graphene Devices for Mass Transport

A Barreiro Megino, R Rurali, ER Hernandez, A Bachtold

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

Abstract

The reversible atomic-mass transport along graphene devices has been achieved. The motion of Al and Au in the form of atoms or clusters is driven by applying an electric field between the metal electrodes that contact the graphene sheet. It is shown that Al moves in the direction of the applied electric field whereas Au tends to diffuse in all directions. The control of the motion of Al is further demonstrated by achieving a 90° turn, using a graphene device patterned in a crossroads configuration. The controlled motion of Al is attributed to the charge transfer from Al onto the graphene so that the Al is effectively charged and can be accelerated by the applied electric field. To get further insight into the actuation mechanism, theoretical simulations of individual Al and Au impurities on a perfect graphene sheet were performed. The direct (electrostatic) force was found to be ~1 pN and dominant over the wind force. These findings hold promise for practical use in future mass transport in complex circuits.

Original language	English
Pages (from-to)	775-780
Number of pages	6
Journal	Small
Volume	7
Issue number	6
Publication status	Published - 2011

Keywords

journal letters, notes, etc.
CWTS JFIS >= 2.00

Cite this

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title = "Structured Graphene Devices for Mass Transport",

abstract = "The reversible atomic-mass transport along graphene devices has been achieved. The motion of Al and Au in the form of atoms or clusters is driven by applying an electric field between the metal electrodes that contact the graphene sheet. It is shown that Al moves in the direction of the applied electric field whereas Au tends to diffuse in all directions. The control of the motion of Al is further demonstrated by achieving a 90° turn, using a graphene device patterned in a crossroads configuration. The controlled motion of Al is attributed to the charge transfer from Al onto the graphene so that the Al is effectively charged and can be accelerated by the applied electric field. To get further insight into the actuation mechanism, theoretical simulations of individual Al and Au impurities on a perfect graphene sheet were performed. The direct (electrostatic) force was found to be ~1 pN and dominant over the wind force. These findings hold promise for practical use in future mass transport in complex circuits.",

keywords = "journal letters, notes, etc., CWTS JFIS >= 2.00",

author = "{Barreiro Megino}, A and R Rurali and ER Hernandez and A Bachtold",

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journal = "Small",

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T1 - Structured Graphene Devices for Mass Transport

AU - Barreiro Megino, A

AU - Rurali, R

AU - Hernandez, ER

AU - Bachtold, A

PY - 2011

Y1 - 2011

N2 - The reversible atomic-mass transport along graphene devices has been achieved. The motion of Al and Au in the form of atoms or clusters is driven by applying an electric field between the metal electrodes that contact the graphene sheet. It is shown that Al moves in the direction of the applied electric field whereas Au tends to diffuse in all directions. The control of the motion of Al is further demonstrated by achieving a 90° turn, using a graphene device patterned in a crossroads configuration. The controlled motion of Al is attributed to the charge transfer from Al onto the graphene so that the Al is effectively charged and can be accelerated by the applied electric field. To get further insight into the actuation mechanism, theoretical simulations of individual Al and Au impurities on a perfect graphene sheet were performed. The direct (electrostatic) force was found to be ~1 pN and dominant over the wind force. These findings hold promise for practical use in future mass transport in complex circuits.

AB - The reversible atomic-mass transport along graphene devices has been achieved. The motion of Al and Au in the form of atoms or clusters is driven by applying an electric field between the metal electrodes that contact the graphene sheet. It is shown that Al moves in the direction of the applied electric field whereas Au tends to diffuse in all directions. The control of the motion of Al is further demonstrated by achieving a 90° turn, using a graphene device patterned in a crossroads configuration. The controlled motion of Al is attributed to the charge transfer from Al onto the graphene so that the Al is effectively charged and can be accelerated by the applied electric field. To get further insight into the actuation mechanism, theoretical simulations of individual Al and Au impurities on a perfect graphene sheet were performed. The direct (electrostatic) force was found to be ~1 pN and dominant over the wind force. These findings hold promise for practical use in future mass transport in complex circuits.

KW - journal letters, notes, etc.

KW - CWTS JFIS >= 2.00

M3 - Article

SN - 1613-6810

VL - 7

SP - 775

EP - 780

JO - Small

JF - Small

IS - 6

ER -

Structured Graphene Devices for Mass Transport

Abstract

Keywords

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