Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold

Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold

Transformation of light carrying spin angular momentum (SAM) to optical field vortices carrying orbital angular momentum (OAM) has been of wide interest in recent years. The interactions between two optical fields, each carrying one of those degrees of freedom, and furthermore, the transfer of the r...

Full description

Bibliographic Details
Main Authors: G. Spektor, D. Kilbane, A. K. Mahro, M. Hartelt, E. Prinz, M. Aeschlimann, M. Orenstein
Format: Article
Language:English
Published: American Physical Society 2019-05-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.9.021031
id doaj-cfc9b857b98b47588e193b8902de9697
record_format Article
spelling doaj-cfc9b857b98b47588e193b8902de96972020-11-24T20:42:10ZengAmerican Physical SocietyPhysical Review X2160-33082019-05-019202103110.1103/PhysRevX.9.021031Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in GoldG. SpektorD. KilbaneA. K. MahroM. HarteltE. PrinzM. AeschlimannM. OrensteinTransformation of light carrying spin angular momentum (SAM) to optical field vortices carrying orbital angular momentum (OAM) has been of wide interest in recent years. The interactions between two optical fields, each carrying one of those degrees of freedom, and furthermore, the transfer of the resulting angular momentum product to matter are seldom discussed. Here, we measure the interaction between 3D light carrying axial SAM and 2D plasmon-polariton vortices carrying high-order transverse OAM. The interaction is mediated by two-photon absorption within a gold surface, imprinting the resulting angular-momentum mixing into matter by excitation of electrons that are photo-emitted into vacuum. Interestingly, the spatial distribution of the emitted electrons carries the signature of a subtraction of the spin from the orbit angular momenta. We show experimentally and theoretically that the absorptive nature of this interaction leads to both single and double photon-plasmon angular momentum mixing processes by one- and two- photon interactions. Our results demonstrate high order angular momenta light-matter interactions, provide a glimpse into specific electronic excitation routes, and may be applied in future electronic sources and coherent control.http://doi.org/10.1103/PhysRevX.9.021031
collection DOAJ
language English
format Article
sources DOAJ
author G. Spektor
D. Kilbane
A. K. Mahro
M. Hartelt
E. Prinz
M. Aeschlimann
M. Orenstein
spellingShingle G. Spektor
D. Kilbane
A. K. Mahro
M. Hartelt
E. Prinz
M. Aeschlimann
M. Orenstein
Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold
Physical Review X
author_facet G. Spektor
D. Kilbane
A. K. Mahro
M. Hartelt
E. Prinz
M. Aeschlimann
M. Orenstein
author_sort G. Spektor
title Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold
title_short Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold
title_full Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold
title_fullStr Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold
title_full_unstemmed Mixing the Light Spin with Plasmon Orbit by Nonlinear Light-Matter Interaction in Gold
title_sort mixing the light spin with plasmon orbit by nonlinear light-matter interaction in gold
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2019-05-01
description Transformation of light carrying spin angular momentum (SAM) to optical field vortices carrying orbital angular momentum (OAM) has been of wide interest in recent years. The interactions between two optical fields, each carrying one of those degrees of freedom, and furthermore, the transfer of the resulting angular momentum product to matter are seldom discussed. Here, we measure the interaction between 3D light carrying axial SAM and 2D plasmon-polariton vortices carrying high-order transverse OAM. The interaction is mediated by two-photon absorption within a gold surface, imprinting the resulting angular-momentum mixing into matter by excitation of electrons that are photo-emitted into vacuum. Interestingly, the spatial distribution of the emitted electrons carries the signature of a subtraction of the spin from the orbit angular momenta. We show experimentally and theoretically that the absorptive nature of this interaction leads to both single and double photon-plasmon angular momentum mixing processes by one- and two- photon interactions. Our results demonstrate high order angular momenta light-matter interactions, provide a glimpse into specific electronic excitation routes, and may be applied in future electronic sources and coherent control.
url http://doi.org/10.1103/PhysRevX.9.021031
work_keys_str_mv AT gspektor mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
AT dkilbane mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
AT akmahro mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
AT mhartelt mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
AT eprinz mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
AT maeschlimann mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
AT morenstein mixingthelightspinwithplasmonorbitbynonlinearlightmatterinteractioningold
_version_ 1716823026676269056

Similar Items