Tomographic imaging of molecular orbitals

J. Itatani; J. Lavesque; D. Zeidler; Hiromichi Niikura; H. Pépin; J. C. Kieffer; P. B. Corkum; D. M. Villeneuve

doi:10.1038/nature03183

Tomographic imaging of molecular orbitals

J. Itatani, J. Lavesque, D. Zeidler, Hiromichi Niikura, H. Pépin, J. C. Kieffer, P. B. Corkum, D. M. Villeneuve^*

^*この研究の対応する著者

研究成果: Article › 査読

1619 被引用数 (Scopus)

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Single-electron wavefunctions, or orbitals, are the mathematical constructs used to describe the multi-electron wavefunction of molecules. Because the highest-lying orbitals are responsible for chemical properties, they are of particular interest To observe these orbitals change as bonds are formed and broken is to observe the essence of chemistry. Yet single orbitals are difficult to observe experimentally, and until now, this has been impossible on the timescale of chemical reactions. Here we demonstrate that the full three-dimensional structure of a single orbital can be imaged by a seemingly unlikely technique, using high harmonics generated from intense femtosecond laser pulses focused on aligned molecules. Applying this approach to a series of molecular alignments, we accomplish a tomographic reconstruction of the highest occupied molecular orbital of N₂. The method also allows us to follow the attosecond dynamics of an electron wave packet.

本文言語	English
ページ（範囲）	867-871
ページ数	5
ジャーナル	Nature
巻	432
号	7019
DOI	https://doi.org/10.1038/nature03183
出版ステータス	Published - 2004 12月 16
外部発表	はい

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title = "Tomographic imaging of molecular orbitals",

abstract = "Single-electron wavefunctions, or orbitals, are the mathematical constructs used to describe the multi-electron wavefunction of molecules. Because the highest-lying orbitals are responsible for chemical properties, they are of particular interest To observe these orbitals change as bonds are formed and broken is to observe the essence of chemistry. Yet single orbitals are difficult to observe experimentally, and until now, this has been impossible on the timescale of chemical reactions. Here we demonstrate that the full three-dimensional structure of a single orbital can be imaged by a seemingly unlikely technique, using high harmonics generated from intense femtosecond laser pulses focused on aligned molecules. Applying this approach to a series of molecular alignments, we accomplish a tomographic reconstruction of the highest occupied molecular orbital of N2. The method also allows us to follow the attosecond dynamics of an electron wave packet.",

author = "J. Itatani and J. Lavesque and D. Zeidler and Hiromichi Niikura and H. P{\'e}pin and Kieffer, {J. C.} and Corkum, {P. B.} and Villeneuve, {D. M.}",

note = "Funding Information: Acknowledgements In addition to the NRC, we acknowledge financial support from the National Science and Engineering Research Council, Photonic Research Ontario, the Canadian Institute for Photonic Innovation, the Alexander von Humboldt-Stiftung and the Japan Society for the Promotion of Science. We thank M. Yu. Ivanov, M. Spanner, J. P. Marangos, M. Lein, P. H. Bucksbaum, I. A. Walmsley, D. Jonas, J. Tse and J. G. Underwood for discussions.",

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AU - Itatani, J.

AU - Lavesque, J.

AU - Zeidler, D.

AU - Niikura, Hiromichi

AU - Pépin, H.

AU - Kieffer, J. C.

AU - Corkum, P. B.

AU - Villeneuve, D. M.

N1 - Funding Information: Acknowledgements In addition to the NRC, we acknowledge financial support from the National Science and Engineering Research Council, Photonic Research Ontario, the Canadian Institute for Photonic Innovation, the Alexander von Humboldt-Stiftung and the Japan Society for the Promotion of Science. We thank M. Yu. Ivanov, M. Spanner, J. P. Marangos, M. Lein, P. H. Bucksbaum, I. A. Walmsley, D. Jonas, J. Tse and J. G. Underwood for discussions.

PY - 2004/12/16

Y1 - 2004/12/16

N2 - Single-electron wavefunctions, or orbitals, are the mathematical constructs used to describe the multi-electron wavefunction of molecules. Because the highest-lying orbitals are responsible for chemical properties, they are of particular interest To observe these orbitals change as bonds are formed and broken is to observe the essence of chemistry. Yet single orbitals are difficult to observe experimentally, and until now, this has been impossible on the timescale of chemical reactions. Here we demonstrate that the full three-dimensional structure of a single orbital can be imaged by a seemingly unlikely technique, using high harmonics generated from intense femtosecond laser pulses focused on aligned molecules. Applying this approach to a series of molecular alignments, we accomplish a tomographic reconstruction of the highest occupied molecular orbital of N2. The method also allows us to follow the attosecond dynamics of an electron wave packet.

AB - Single-electron wavefunctions, or orbitals, are the mathematical constructs used to describe the multi-electron wavefunction of molecules. Because the highest-lying orbitals are responsible for chemical properties, they are of particular interest To observe these orbitals change as bonds are formed and broken is to observe the essence of chemistry. Yet single orbitals are difficult to observe experimentally, and until now, this has been impossible on the timescale of chemical reactions. Here we demonstrate that the full three-dimensional structure of a single orbital can be imaged by a seemingly unlikely technique, using high harmonics generated from intense femtosecond laser pulses focused on aligned molecules. Applying this approach to a series of molecular alignments, we accomplish a tomographic reconstruction of the highest occupied molecular orbital of N2. The method also allows us to follow the attosecond dynamics of an electron wave packet.

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Tomographic imaging of molecular orbitals

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