Phase of the electric field localized at surface-immobilized gold nanospheres determined by second-harmonic interferometry

Tatsuya Yamaguchi; Haruki Okawa; Kazuhiko Hashimoto; Masayuki Shimojo; Kotaro Kajikawa

doi:10.1103/PhysRevB.83.085425

Phase of the electric field localized at surface-immobilized gold nanospheres determined by second-harmonic interferometry

Tatsuya Yamaguchi, Haruki Okawa, Kazuhiko Hashimoto, Masayuki Shimojo, Kotaro Kajikawa

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

5 Citations (Scopus)

Abstract

Gold nanospheres immobilized above a gold surface, with a nanometer gap between, comprise a promising plasmonic system. Although many works have studied the magnitude of the enhanced electric fields that are localized at the plasmonic nanostructure, little is known about their phase. To probe the phase of the electric field localized adjacent to the plasmonic nanostructure, we undertook interferometry for second-harmonic (SH) light from hemicyanine monolayers on the surface-immobilized gold nanospheres (SIGNs), and from a hemicyanine monolayer in the nanogap. The SH phase from the hemicyanine monolayer on the SIGNs was found to be almost opposite to that from the hemicyanine monolayer in the nanogap. This result is supported by a theoretical calculation of the localized electric fields based on higher order multipoles.

Original language	English
Article number	085425
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	83
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevB.83.085425
Publication status	Published - 2011 Feb 28
Externally published	Yes

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.83.085425

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abstract = "Gold nanospheres immobilized above a gold surface, with a nanometer gap between, comprise a promising plasmonic system. Although many works have studied the magnitude of the enhanced electric fields that are localized at the plasmonic nanostructure, little is known about their phase. To probe the phase of the electric field localized adjacent to the plasmonic nanostructure, we undertook interferometry for second-harmonic (SH) light from hemicyanine monolayers on the surface-immobilized gold nanospheres (SIGNs), and from a hemicyanine monolayer in the nanogap. The SH phase from the hemicyanine monolayer on the SIGNs was found to be almost opposite to that from the hemicyanine monolayer in the nanogap. This result is supported by a theoretical calculation of the localized electric fields based on higher order multipoles.",

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AU - Yamaguchi, Tatsuya

AU - Okawa, Haruki

AU - Hashimoto, Kazuhiko

AU - Shimojo, Masayuki

AU - Kajikawa, Kotaro

PY - 2011/2/28

Y1 - 2011/2/28

N2 - Gold nanospheres immobilized above a gold surface, with a nanometer gap between, comprise a promising plasmonic system. Although many works have studied the magnitude of the enhanced electric fields that are localized at the plasmonic nanostructure, little is known about their phase. To probe the phase of the electric field localized adjacent to the plasmonic nanostructure, we undertook interferometry for second-harmonic (SH) light from hemicyanine monolayers on the surface-immobilized gold nanospheres (SIGNs), and from a hemicyanine monolayer in the nanogap. The SH phase from the hemicyanine monolayer on the SIGNs was found to be almost opposite to that from the hemicyanine monolayer in the nanogap. This result is supported by a theoretical calculation of the localized electric fields based on higher order multipoles.

AB - Gold nanospheres immobilized above a gold surface, with a nanometer gap between, comprise a promising plasmonic system. Although many works have studied the magnitude of the enhanced electric fields that are localized at the plasmonic nanostructure, little is known about their phase. To probe the phase of the electric field localized adjacent to the plasmonic nanostructure, we undertook interferometry for second-harmonic (SH) light from hemicyanine monolayers on the surface-immobilized gold nanospheres (SIGNs), and from a hemicyanine monolayer in the nanogap. The SH phase from the hemicyanine monolayer on the SIGNs was found to be almost opposite to that from the hemicyanine monolayer in the nanogap. This result is supported by a theoretical calculation of the localized electric fields based on higher order multipoles.

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Phase of the electric field localized at surface-immobilized gold nanospheres determined by second-harmonic interferometry

Abstract

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