Controlling organic reactions on silicon surfaces with a scanning tunneling microscope: Theoretical and experimental studies of resonance-mediated desorption

Saman Alavi; Roger Rousseau; Gregory P. Lopinski; Robert A. Wolkow; Tamar Seideman

doi:10.1039/b004093m

Controlling organic reactions on silicon surfaces with a scanning tunneling microscope: Theoretical and experimental studies of resonance-mediated desorption

Saman Alavi, Roger Rousseau, Gregory P. Lopinski, Robert A. Wolkow, Tamar Seideman

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

33 Scopus citations

Abstract

The dynamics of tip-induced, resonance-mediated bond-breaking in complex organic adsorbates is studied theoretically and experimentally. Desorption of benzene from a Si(100) surface is found to be efficient and sensitive to voltage, the measured yield rising from below 10^-10 to ca. 10^-6 per electron within a ca. 0.8 V range at low ( < 100 pA) current. A theoretical model, based upon first principles electronic structure calculations and quantum mechanical wavepacket simulations, traces these observations to multi-mode dynamics triggered by a transition into a cationic resonance. The model is generalized to provide understanding of, and suggest a means of control over, the behaviour of different classes of organic adsorbates under tunneling current.

Original language	English
Pages (from-to)	213-229
Number of pages	17
Journal	Faraday Discussions
Volume	117
DOIs	https://doi.org/10.1039/b004093m
State	Published - 2000
Externally published	Yes

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title = "Controlling organic reactions on silicon surfaces with a scanning tunneling microscope: Theoretical and experimental studies of resonance-mediated desorption",

abstract = "The dynamics of tip-induced, resonance-mediated bond-breaking in complex organic adsorbates is studied theoretically and experimentally. Desorption of benzene from a Si(100) surface is found to be efficient and sensitive to voltage, the measured yield rising from below 10-10 to ca. 10-6 per electron within a ca. 0.8 V range at low ( < 100 pA) current. A theoretical model, based upon first principles electronic structure calculations and quantum mechanical wavepacket simulations, traces these observations to multi-mode dynamics triggered by a transition into a cationic resonance. The model is generalized to provide understanding of, and suggest a means of control over, the behaviour of different classes of organic adsorbates under tunneling current.",

author = "Saman Alavi and Roger Rousseau and Lopinski, \{Gregory P.\} and Wolkow, \{Robert A.\} and Tamar Seideman",

year = "2000",

doi = "10.1039/b004093m",

language = "English",

volume = "117",

pages = "213--229",

journal = "Faraday Discussions",

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publisher = "Royal Society of Chemistry",

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T1 - Controlling organic reactions on silicon surfaces with a scanning tunneling microscope

T2 - Theoretical and experimental studies of resonance-mediated desorption

AU - Alavi, Saman

AU - Rousseau, Roger

AU - Lopinski, Gregory P.

AU - Wolkow, Robert A.

AU - Seideman, Tamar

PY - 2000

Y1 - 2000

N2 - The dynamics of tip-induced, resonance-mediated bond-breaking in complex organic adsorbates is studied theoretically and experimentally. Desorption of benzene from a Si(100) surface is found to be efficient and sensitive to voltage, the measured yield rising from below 10-10 to ca. 10-6 per electron within a ca. 0.8 V range at low ( < 100 pA) current. A theoretical model, based upon first principles electronic structure calculations and quantum mechanical wavepacket simulations, traces these observations to multi-mode dynamics triggered by a transition into a cationic resonance. The model is generalized to provide understanding of, and suggest a means of control over, the behaviour of different classes of organic adsorbates under tunneling current.

AB - The dynamics of tip-induced, resonance-mediated bond-breaking in complex organic adsorbates is studied theoretically and experimentally. Desorption of benzene from a Si(100) surface is found to be efficient and sensitive to voltage, the measured yield rising from below 10-10 to ca. 10-6 per electron within a ca. 0.8 V range at low ( < 100 pA) current. A theoretical model, based upon first principles electronic structure calculations and quantum mechanical wavepacket simulations, traces these observations to multi-mode dynamics triggered by a transition into a cationic resonance. The model is generalized to provide understanding of, and suggest a means of control over, the behaviour of different classes of organic adsorbates under tunneling current.

UR - https://www.scopus.com/pages/publications/0345423042

U2 - 10.1039/b004093m

DO - 10.1039/b004093m

M3 - Article

AN - SCOPUS:0345423042

SN - 1359-6640

VL - 117

SP - 213

EP - 229

JO - Faraday Discussions

JF - Faraday Discussions

ER -

Controlling organic reactions on silicon surfaces with a scanning tunneling microscope: Theoretical and experimental studies of resonance-mediated desorption

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