Recent advances in ultrafast plasmonics: from strong field physics to ultraprecision spectroscopy

San Kim; Tae-In Jeong; Jongkyoon Park; Marcelo F. Ciappina; Seungchul Kim

doi:10.1515/nanoph-2021-0694

Recent advances in ultrafast plasmonics: from strong field physics to ultraprecision spectroscopy

San Kim, Tae-In Jeong, Jongkyoon Park, Marcelo F. Ciappina^*, Seungchul Kim^*

^*Corresponding author for this work

Physics

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

7 Scopus citations

Abstract

Surface plasmons, the collective oscillation of electrons, enable the manipulation of optical fields with unprecedented spatial and time resolutions. They are the workhorse of a large set of applications, such as chemical/biological sensors or Raman scattering spectroscopy, to name only a few. In particular, the ultrafast optical response configures one of the most fundamental characteristics of surface plasmons. Thus, the rich physics about photon–electron interactions could be retrieved and studied in detail. The associated plasmon-enhanced electric fields, generated by focusing the surface plasmons far beyond the diffraction limit, allow reaching the strong field regime with relatively low input laser intensities. This is in clear contrast to conventional optical methods, where their intrinsic limitations demand the use of large and costly laser amplifiers, to attain high electric fields, able to manipulate the electron dynamics in the non-linear regime. Moreover, the coherent plasmonic field excited by the optical field inherits an ultrahigh precision that could be properly exploited in, for instance, ultraprecision spectroscopy. In this review, we summarize the research achievements and developments in ultrafast plasmonics over the last decade. We particularly emphasize the strong-field physics aspects and the ultraprecision spectroscopy using optical frequency combs.

Original language	English
Journal	Nanophotonics
DOIs	https://doi.org/10.1515/nanoph-2021-0694
State	E-pub ahead of print - 21 Mar 2022

Keywords

optical frequency comb
photoelectron spectroscopy
strong-field physics
surface plasmons
ultrafast plasmonics

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@article{8bdf244c8306460a988dc2b4e66878d8,

title = "Recent advances in ultrafast plasmonics: from strong field physics to ultraprecision spectroscopy",

abstract = "Surface plasmons, the collective oscillation of electrons, enable the manipulation of optical fields with unprecedented spatial and time resolutions. They are the workhorse of a large set of applications, such as chemical/biological sensors or Raman scattering spectroscopy, to name only a few. In particular, the ultrafast optical response configures one of the most fundamental characteristics of surface plasmons. Thus, the rich physics about photon–electron interactions could be retrieved and studied in detail. The associated plasmon-enhanced electric fields, generated by focusing the surface plasmons far beyond the diffraction limit, allow reaching the strong field regime with relatively low input laser intensities. This is in clear contrast to conventional optical methods, where their intrinsic limitations demand the use of large and costly laser amplifiers, to attain high electric fields, able to manipulate the electron dynamics in the non-linear regime. Moreover, the coherent plasmonic field excited by the optical field inherits an ultrahigh precision that could be properly exploited in, for instance, ultraprecision spectroscopy. In this review, we summarize the research achievements and developments in ultrafast plasmonics over the last decade. We particularly emphasize the strong-field physics aspects and the ultraprecision spectroscopy using optical frequency combs.",

keywords = "optical frequency comb, photoelectron spectroscopy, strong-field physics, surface plasmons, ultrafast plasmonics",

author = "San Kim and Tae-In Jeong and Jongkyoon Park and Ciappina, {Marcelo F.} and Seungchul Kim",

year = "2022",

month = mar,

day = "21",

doi = "10.1515/nanoph-2021-0694",

language = "英语",

journal = "Nanophotonics",

issn = "2192-8606",

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AU - Kim, San

AU - Jeong, Tae-In

AU - Park, Jongkyoon

AU - Ciappina, Marcelo F.

AU - Kim, Seungchul

PY - 2022/3/21

Y1 - 2022/3/21

N2 - Surface plasmons, the collective oscillation of electrons, enable the manipulation of optical fields with unprecedented spatial and time resolutions. They are the workhorse of a large set of applications, such as chemical/biological sensors or Raman scattering spectroscopy, to name only a few. In particular, the ultrafast optical response configures one of the most fundamental characteristics of surface plasmons. Thus, the rich physics about photon–electron interactions could be retrieved and studied in detail. The associated plasmon-enhanced electric fields, generated by focusing the surface plasmons far beyond the diffraction limit, allow reaching the strong field regime with relatively low input laser intensities. This is in clear contrast to conventional optical methods, where their intrinsic limitations demand the use of large and costly laser amplifiers, to attain high electric fields, able to manipulate the electron dynamics in the non-linear regime. Moreover, the coherent plasmonic field excited by the optical field inherits an ultrahigh precision that could be properly exploited in, for instance, ultraprecision spectroscopy. In this review, we summarize the research achievements and developments in ultrafast plasmonics over the last decade. We particularly emphasize the strong-field physics aspects and the ultraprecision spectroscopy using optical frequency combs.

AB - Surface plasmons, the collective oscillation of electrons, enable the manipulation of optical fields with unprecedented spatial and time resolutions. They are the workhorse of a large set of applications, such as chemical/biological sensors or Raman scattering spectroscopy, to name only a few. In particular, the ultrafast optical response configures one of the most fundamental characteristics of surface plasmons. Thus, the rich physics about photon–electron interactions could be retrieved and studied in detail. The associated plasmon-enhanced electric fields, generated by focusing the surface plasmons far beyond the diffraction limit, allow reaching the strong field regime with relatively low input laser intensities. This is in clear contrast to conventional optical methods, where their intrinsic limitations demand the use of large and costly laser amplifiers, to attain high electric fields, able to manipulate the electron dynamics in the non-linear regime. Moreover, the coherent plasmonic field excited by the optical field inherits an ultrahigh precision that could be properly exploited in, for instance, ultraprecision spectroscopy. In this review, we summarize the research achievements and developments in ultrafast plasmonics over the last decade. We particularly emphasize the strong-field physics aspects and the ultraprecision spectroscopy using optical frequency combs.

KW - optical frequency comb

KW - photoelectron spectroscopy

KW - strong-field physics

KW - surface plasmons

KW - ultrafast plasmonics

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DO - 10.1515/nanoph-2021-0694

M3 - 文章

SN - 2192-8606

JO - Nanophotonics

JF - Nanophotonics

ER -

Recent advances in ultrafast plasmonics: from strong field physics to ultraprecision spectroscopy

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