Imaging the Nonlinear Plasmoemission Dynamics of Electrons from Strong Plasmonic Fields

We use subcycle time-resolved photoemission microscopy to unambiguously distinguish optically triggered electron emission (photoemission) from effects caused purely by the plasmonic field (termed “plasmoemission”). We find from time-resolved imaging that nonlinear plasmoemission is dominated by the...

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Published in	Nano letters Vol. 17; no. 11; pp. 6569 - 6574
Main Authors	Podbiel, Daniel, Kahl, Philip, Makris, Andreas, Frank, Bettina, Sindermann, Simon, Davis, Timothy J, Giessen, Harald, Hoegen, Michael Horn-von, Meyer zu Heringdorf, Frank-J
Format	Journal Article
Language	English
Published	United States American Chemical Society 08.11.2017
Subjects	photoemission Time-resolved photoemission microscopy plasmoemission above-threshold photoemission surface plasmon polariton
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Abstract	We use subcycle time-resolved photoemission microscopy to unambiguously distinguish optically triggered electron emission (photoemission) from effects caused purely by the plasmonic field (termed “plasmoemission”). We find from time-resolved imaging that nonlinear plasmoemission is dominated by the transverse plasmon field component by utilizing a transient standing wave from two counter-propagating plasmon pulses of opposite transverse spin. From plasmonic foci on flat metal surfaces, we observe highly nonlinear plasmoemission up to the fifth power of intensity and quantized energy transfer, which reflects the quantum-mechanical nature of surface plasmons. Our work constitutes the basis for novel plasmonic devices such as nanometer-confined ultrafast electron sources as well as applications in time-resolved electron microscopy.
AbstractList	We use subcycle time-resolved photoemission microscopy to unambiguously distinguish optically triggered electron emission (photoemission) from effects caused purely by the plasmonic field (termed "plasmoemission"). We find from time-resolved imaging that nonlinear plasmoemission is dominated by the transverse plasmon field component by utilizing a transient standing wave from two counter-propagating plasmon pulses of opposite transverse spin. From plasmonic foci on flat metal surfaces, we observe highly nonlinear plasmoemission up to the fifth power of intensity and quantized energy transfer, which reflects the quantum-mechanical nature of surface plasmons. Our work constitutes the basis for novel plasmonic devices such as nanometer-confined ultrafast electron sources as well as applications in time-resolved electron microscopy.We use subcycle time-resolved photoemission microscopy to unambiguously distinguish optically triggered electron emission (photoemission) from effects caused purely by the plasmonic field (termed "plasmoemission"). We find from time-resolved imaging that nonlinear plasmoemission is dominated by the transverse plasmon field component by utilizing a transient standing wave from two counter-propagating plasmon pulses of opposite transverse spin. From plasmonic foci on flat metal surfaces, we observe highly nonlinear plasmoemission up to the fifth power of intensity and quantized energy transfer, which reflects the quantum-mechanical nature of surface plasmons. Our work constitutes the basis for novel plasmonic devices such as nanometer-confined ultrafast electron sources as well as applications in time-resolved electron microscopy. We use subcycle time-resolved photoemission microscopy to unambiguously distinguish optically triggered electron emission (photoemission) from effects caused purely by the plasmonic field (termed "plasmoemission"). We find from time-resolved imaging that nonlinear plasmoemission is dominated by the transverse plasmon field component by utilizing a transient standing wave from two counter-propagating plasmon pulses of opposite transverse spin. From plasmonic foci on flat metal surfaces, we observe highly nonlinear plasmoemission up to the fifth power of intensity and quantized energy transfer, which reflects the quantum-mechanical nature of surface plasmons. Our work constitutes the basis for novel plasmonic devices such as nanometer-confined ultrafast electron sources as well as applications in time-resolved electron microscopy.
Author	Kahl, Philip Giessen, Harald Podbiel, Daniel Meyer zu Heringdorf, Frank-J Frank, Bettina Davis, Timothy J Sindermann, Simon Hoegen, Michael Horn-von Makris, Andreas
AuthorAffiliation	University of Stuttgart University of Duisburg-Essen Fourth Physics Institute and Research Center SCoPE Faculty of Physics and CENIDE School of Physics
AuthorAffiliation_xml	– name: University of Duisburg-Essen – name: School of Physics – name: Faculty of Physics and CENIDE – name: Fourth Physics Institute and Research Center SCoPE – name: University of Stuttgart
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