Real-time observation of collective excitations in photoemission

C. Lemell; S. Neppl; G. Wachter; K. Tokési; R. Ernstorfer; P. Feulner; R. Kienberger; J. Burgdörfer

doi:10.1103/PhysRevB.91.241101

Real-time observation of collective excitations in photoemission

C. Lemell, S. Neppl, G. Wachter, K. Tokési, R. Ernstorfer, P. Feulner, R. Kienberger, J. Burgdörfer

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34 Scopus citations

Abstract

Ejection of an electron by absorption of an extreme ultraviolet (xuv) photon probes the many-electron response of a solid well beyond the single-particle picture. Photoemission spectra feature complex correlation satellite structures signifying the simultaneous excitation of single or multiple plasmons. The time delay of the plasmon satellites relative to the main line can be resolved in attosecond streaking experiments. Time-resolved photoemission thus provides the key to discriminate between intrinsic and extrinsic plasmon excitation. We demonstrate the determination of the branching ratio between intrinsic and extrinsic plasmon generation for simple metals.

Original language	English
Article number	241101
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	91
Issue number	24
DOIs	https://doi.org/10.1103/PhysRevB.91.241101
State	Published - 3 Jun 2015

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10.1103/PhysRevB.91.241101

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title = "Real-time observation of collective excitations in photoemission",

abstract = "Ejection of an electron by absorption of an extreme ultraviolet (xuv) photon probes the many-electron response of a solid well beyond the single-particle picture. Photoemission spectra feature complex correlation satellite structures signifying the simultaneous excitation of single or multiple plasmons. The time delay of the plasmon satellites relative to the main line can be resolved in attosecond streaking experiments. Time-resolved photoemission thus provides the key to discriminate between intrinsic and extrinsic plasmon excitation. We demonstrate the determination of the branching ratio between intrinsic and extrinsic plasmon generation for simple metals.",

author = "C. Lemell and S. Neppl and G. Wachter and K. Tok{\'e}si and R. Ernstorfer and P. Feulner and R. Kienberger and J. Burgd{\"o}rfer",

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AU - Lemell, C.

AU - Neppl, S.

AU - Wachter, G.

AU - Tokési, K.

AU - Ernstorfer, R.

AU - Feulner, P.

AU - Kienberger, R.

AU - Burgdörfer, J.

PY - 2015/6/3

Y1 - 2015/6/3

N2 - Ejection of an electron by absorption of an extreme ultraviolet (xuv) photon probes the many-electron response of a solid well beyond the single-particle picture. Photoemission spectra feature complex correlation satellite structures signifying the simultaneous excitation of single or multiple plasmons. The time delay of the plasmon satellites relative to the main line can be resolved in attosecond streaking experiments. Time-resolved photoemission thus provides the key to discriminate between intrinsic and extrinsic plasmon excitation. We demonstrate the determination of the branching ratio between intrinsic and extrinsic plasmon generation for simple metals.

AB - Ejection of an electron by absorption of an extreme ultraviolet (xuv) photon probes the many-electron response of a solid well beyond the single-particle picture. Photoemission spectra feature complex correlation satellite structures signifying the simultaneous excitation of single or multiple plasmons. The time delay of the plasmon satellites relative to the main line can be resolved in attosecond streaking experiments. Time-resolved photoemission thus provides the key to discriminate between intrinsic and extrinsic plasmon excitation. We demonstrate the determination of the branching ratio between intrinsic and extrinsic plasmon generation for simple metals.

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DO - 10.1103/PhysRevB.91.241101

M3 - Article

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VL - 91

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 24

M1 - 241101

ER -

Real-time observation of collective excitations in photoemission

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