Vibration-assisted rotation and deprotonation of a single formic acid molecule adsorbed on Ni(110) studied by scanning tunneling microscopy

Satoshi Katano; Yousoo Kim; Yuma Kagata; Maki Kawai

doi:10.1021/jp906627g

Vibration-assisted rotation and deprotonation of a single formic acid molecule adsorbed on Ni(110) studied by scanning tunneling microscopy

Satoshi Katano, Yousoo Kim, Yuma Kagata, Maki Kawai

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

16 Citations (Scopus)

Abstract

We have studied the reaction of a single molecule of formic acid adsorbed on the Ni(110) surface using a scanning tunneling microscope (STM) at cryogenic temperatures. At 50 K, formic acid molecules, having an O-H bond, were converted to formate via thermal dissociation of the O-H bond, whereas deuterated formic acid molecules, having O-D, are adsorbed intact. By injecting tunneling electrons from the STM tip into individual formic acid molecules, we have selectively controlled two types of reactions: rotational motion and O-H bond dissociation to form formate. Injection of the tunneling electrons at various voltages indicates that significant enhancements in the reaction probability are due to the excitation of specific vibrational modes, that is, C-O stretching and O-D stretching modes of formic acid.

Original language	English
Pages (from-to)	19277-19280
Number of pages	4
Journal	Journal of Physical Chemistry C
Volume	113
Issue number	44
DOIs	https://doi.org/10.1021/jp906627g
Publication status	Published - 2009 Nov 20
Externally published	Yes

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Energy(all)
Physical and Theoretical Chemistry
Surfaces, Coatings and Films

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abstract = "We have studied the reaction of a single molecule of formic acid adsorbed on the Ni(110) surface using a scanning tunneling microscope (STM) at cryogenic temperatures. At 50 K, formic acid molecules, having an O-H bond, were converted to formate via thermal dissociation of the O-H bond, whereas deuterated formic acid molecules, having O-D, are adsorbed intact. By injecting tunneling electrons from the STM tip into individual formic acid molecules, we have selectively controlled two types of reactions: rotational motion and O-H bond dissociation to form formate. Injection of the tunneling electrons at various voltages indicates that significant enhancements in the reaction probability are due to the excitation of specific vibrational modes, that is, C-O stretching and O-D stretching modes of formic acid.",

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AU - Katano, Satoshi

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AU - Kagata, Yuma

AU - Kawai, Maki

PY - 2009/11/20

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N2 - We have studied the reaction of a single molecule of formic acid adsorbed on the Ni(110) surface using a scanning tunneling microscope (STM) at cryogenic temperatures. At 50 K, formic acid molecules, having an O-H bond, were converted to formate via thermal dissociation of the O-H bond, whereas deuterated formic acid molecules, having O-D, are adsorbed intact. By injecting tunneling electrons from the STM tip into individual formic acid molecules, we have selectively controlled two types of reactions: rotational motion and O-H bond dissociation to form formate. Injection of the tunneling electrons at various voltages indicates that significant enhancements in the reaction probability are due to the excitation of specific vibrational modes, that is, C-O stretching and O-D stretching modes of formic acid.

AB - We have studied the reaction of a single molecule of formic acid adsorbed on the Ni(110) surface using a scanning tunneling microscope (STM) at cryogenic temperatures. At 50 K, formic acid molecules, having an O-H bond, were converted to formate via thermal dissociation of the O-H bond, whereas deuterated formic acid molecules, having O-D, are adsorbed intact. By injecting tunneling electrons from the STM tip into individual formic acid molecules, we have selectively controlled two types of reactions: rotational motion and O-H bond dissociation to form formate. Injection of the tunneling electrons at various voltages indicates that significant enhancements in the reaction probability are due to the excitation of specific vibrational modes, that is, C-O stretching and O-D stretching modes of formic acid.

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Vibration-assisted rotation and deprotonation of a single formic acid molecule adsorbed on Ni(110) studied by scanning tunneling microscopy

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