SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2997397301> ?p ?o ?g. }

Showing items 1 to 100 of ±153 with 100 items per page.

W2997397301 abstract "A theory of the interaction between a radiating dipole and the plasmonic excitations of a spherical metallic nanoshell in the quasistatic approximation is formulated. After a derivation of surface plasmon frequencies and a comparison with the corresponding modes of metal spheres and cavities, we introduce an expression for the effective volume for any position of the dipole inside or outside the nanoshell, describing the local electromagnetic field enhancement in analogy to other cavity-QED systems. The modification of the dipole decay rate is calculated as a function of frequency for various geometrical parameters, and it reflects the spectrum of spherelike and cavity-like surface plasmon excitations. We then give a formulation of emission spectra, suitable for describing light-matter interaction beyond perturbation theory, and study the conditions for the strong coupling regime to occur. By suitably tuning the geometrical parameters of the nanoshell and by choosing the order of surface plasmon modes to minimize the effective volume, a vacuum Rabi splitting can occur in emission spectra for dipole oscillator strengths as small as a few units, which can be easily achieved with organic molecules or quantum dots. The most favorable situation for strong coupling is when the dipole is located inside the nanoshell. Surprisingly, this dipole couples with spherelike modes more strongly than with cavity-like ones, if the shell is thin enough. As a conclusion, metallic nanoshells turn out to be a suitable platform in order to investigate the strong-coupling regime of light-matter interaction by exploiting surface plasmon resonances." @default.
W2997397301 created "2020-01-10" @default.
W2997397301 creator A5045102280 @default.
W2997397301 creator A5067158005 @default.
W2997397301 creator A5072162410 @default.
W2997397301 date "2012-07-16" @default.
W2997397301 modified "2023-09-27" @default.
W2997397301 title "Surface plasmons and strong light-matter coupling in metallic nanoshells" @default.
W2997397301 cites W1508762865 @default.
W2997397301 cites W1572432597 @default.
W2997397301 cites W1970391517 @default.
W2997397301 cites W1983718136 @default.
W2997397301 cites W1988409034 @default.
W2997397301 cites W1989779244 @default.
W2997397301 cites W1992092936 @default.
W2997397301 cites W1994356604 @default.
W2997397301 cites W1995388873 @default.
W2997397301 cites W2000046762 @default.
W2997397301 cites W2003070696 @default.
W2997397301 cites W2003411680 @default.
W2997397301 cites W2003995109 @default.
W2997397301 cites W2017630019 @default.
W2997397301 cites W2019902160 @default.
W2997397301 cites W2020093054 @default.
W2997397301 cites W2021822161 @default.
W2997397301 cites W2022397315 @default.
W2997397301 cites W2024824810 @default.
W2997397301 cites W2028669679 @default.
W2997397301 cites W2029118753 @default.
W2997397301 cites W2029503730 @default.
W2997397301 cites W2030102959 @default.
W2997397301 cites W2032897937 @default.
W2997397301 cites W2033336611 @default.
W2997397301 cites W2036074131 @default.
W2997397301 cites W2037195913 @default.
W2997397301 cites W2041253196 @default.
W2997397301 cites W2041921807 @default.
W2997397301 cites W2047200178 @default.
W2997397301 cites W2049343351 @default.
W2997397301 cites W2050467638 @default.
W2997397301 cites W2057231857 @default.
W2997397301 cites W2059115563 @default.
W2997397301 cites W2060152947 @default.
W2997397301 cites W2060233480 @default.
W2997397301 cites W2062889700 @default.
W2997397301 cites W2064637791 @default.
W2997397301 cites W2065555548 @default.
W2997397301 cites W2065768648 @default.
W2997397301 cites W2066326476 @default.
W2997397301 cites W2072549768 @default.
W2997397301 cites W2073592087 @default.
W2997397301 cites W2076951286 @default.
W2997397301 cites W2082386486 @default.
W2997397301 cites W2084082511 @default.
W2997397301 cites W2089443328 @default.
W2997397301 cites W2092349245 @default.
W2997397301 cites W2097434829 @default.
W2997397301 cites W2100282116 @default.
W2997397301 cites W2110927120 @default.
W2997397301 cites W2144762664 @default.
W2997397301 cites W2149799609 @default.
W2997397301 cites W2150409916 @default.
W2997397301 cites W2152265295 @default.
W2997397301 cites W2154919444 @default.
W2997397301 cites W2168329539 @default.
W2997397301 cites W2168572786 @default.
W2997397301 cites W2597971488 @default.
W2997397301 cites W3015586612 @default.
W2997397301 cites W3098325613 @default.
W2997397301 cites W3099196813 @default.
W2997397301 cites W3101322627 @default.
W2997397301 cites W3106104018 @default.
W2997397301 cites W3147054964 @default.
W2997397301 cites W3184661802 @default.
W2997397301 cites W4299000585 @default.
W2997397301 doi "https://doi.org/10.1103/physrevb.86.035421" @default.
W2997397301 hasPublicationYear "2012" @default.
W2997397301 type Work @default.
W2997397301 sameAs 2997397301 @default.
W2997397301 citedByCount "41" @default.
W2997397301 countsByYear W29973973012013 @default.
W2997397301 countsByYear W29973973012014 @default.
W2997397301 countsByYear W29973973012015 @default.
W2997397301 countsByYear W29973973012016 @default.
W2997397301 countsByYear W29973973012017 @default.
W2997397301 countsByYear W29973973012018 @default.
W2997397301 countsByYear W29973973012019 @default.
W2997397301 countsByYear W29973973012020 @default.
W2997397301 countsByYear W29973973012021 @default.
W2997397301 countsByYear W29973973012022 @default.
W2997397301 crossrefType "journal-article" @default.
W2997397301 hasAuthorship W2997397301A5045102280 @default.
W2997397301 hasAuthorship W2997397301A5067158005 @default.
W2997397301 hasAuthorship W2997397301A5072162410 @default.
W2997397301 hasConcept C10165471 @default.
W2997397301 hasConcept C106847996 @default.
W2997397301 hasConcept C110879396 @default.
W2997397301 hasConcept C111154242 @default.
W2997397301 hasConcept C120665830 @default.
W2997397301 hasConcept C121332964 @default.