Spectroscopic properties of a two-level atom interacting with a complex spherical nanoshell

Moroz, Alexander

doi:10.1016/j.chemphys.2005.05.003

Cited by 39 publications

(34 citation statements)

References 61 publications

(226 reference statements)

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“…Metallic surfaces are known to increase the local electromagnetic fields and modify both excitation and emission rates of proximate fluorophores, chromophores, and quantum dots [1,2,3,4,5,6,7,8,9,10,11,12]. Especially promising is modifying fluorescence rates by means of metallic nanoparticles (MNPs) for addressing various issues of interest to biology [2,3,4,5].…”

Section: Introductionmentioning

confidence: 99%

Non-radiative decay of a dipole emitter close to a metallic nanoparticle: Importance of higher-order multipole contributions

Moroz

2010

Optics Communications

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a b s t r a c tThe contribution of higher-order multipoles to radiative and non-radiative decay of a single dipole emitter close to a spherical metallic nanoparticle is re-examined. Taking a Ag spherical nanoparticle (AgNP) with the radius of 5 nm as an example, a significant contribution (between 50% and 101% of the total value) of higher-order multipoles to non-radiative rates is found even at the emitter distance of 5 nm from the AgNP surface. On the other hand, the higher-order multipole contribution to radiative rates is negligible. Consequently, a dipole-dipole approximation can yield only an upper bound on the apparent quantum yield. In contrast, the non-radiative rates calculated with the quasistatic Gersten and Nitzan method are found to be in much better agreement with exact electrodynamic results. Finally, the size corrected metal dielectric function is shown to decrease the non-radiative rates near the dipolar surface plasmon resonance.

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Section: Introductionmentioning

confidence: 99%

Non-radiative decay of a dipole emitter close to a metallic nanoparticle: Importance of higher-order multipole contributions

Moroz

2010

Optics Communications

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“…The solution of this problem implies the definition of the electromagnetic field within or outside of a sphere which allows to get its absorption, scattering, extinction or other important characteristics. Among these properties, the cycle-and orientation-averaged electric |E| 2 and magnetic |H| 2 fields (in general, electromagnetic energy) within a particular layer (shell) or in the vicinity of a multilayered sphere is of great importance since it defines performance and suitability of a multilayered sphere for a large number of intriguing applications: nonlinear optics [17][18][19], lasing [20][21][22], heating [23][24][25], photocatalysis [26], fluorescence enhancement [27][28][29][30], plasmon-enhanced upconversion [31,32], energy harvesting and storing [33][34][35][36], surface-enhanced Raman spectroscopy [37][38][39], biology and medicine [40][41][42][43][44].…”

Section: Introductionmentioning

confidence: 99%

Electromagnetic energy in multilayered spherical particles

2019

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We obtain exact analytic expressions for (i) the electromagnetic energy radial density within and outside a multilayered sphere and (ii) the total electromagnetic energy stored within its core and each of its shells. Explicit expressions for the special cases of lossless core and shell are also provided. The general solution is based on compact recursive transfer-matrix method and its validity includes also magnetic media. The theory is illustrated on the examples of electric field enhancement within various metallo-dielectric silica-gold multilayered spheres. User-friendly MATLAB code which includes the theoretical treatment, is available as a supplement to the paper.

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“…A further consideration in fluorescence enhancement experiments is that very close to the metal surface ͑Ͻ10 nm͒, where the field enhancements are highest, coupling to higher-order dark plasmonic modes introduces quenching paths, limiting the effect of plasmon-enhanced luminescence. 6,[20][21][22][23] While the collective scattering and absorption resonances due to the free electrons in the metal shell are now reasonably well studied, there is an additional resonance that has not received much attention. This is the geometric cavity mode that results from confinement of light inside the dielectric core, with the cavity boundaries determined by the metal shell.…”

Section: Introductionmentioning

confidence: 99%

“…The enhanced local fields can be used to enhance the fluorescence emission of dyes close to the metal surface, 1,2 to give increased signals in Raman spectroscopy, 3,4 or to increase the photostability of luminescent dyes by shortening the excited-state lifetime. [5][6][7][8][9] An interesting class of metal nanoparticles are core-shell colloids, composed of a dielectric core surrounded by a metallic shell. The plasmon frequency of these particles can be tuned throughout the visible and near-infrared part of the spectrum by varying core diameter and shell thickness.…”

Section: Introductionmentioning

confidence: 99%

Optical cavity modes in gold shell colloids

Penninkhof

Sweatlock

Moroz

et al. 2008

Journal of Applied Physics

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Core-shell colloids composed of a dielectric core surrounded by a metal shell show geometric cavity resonances with optical properties that are distinctly different than those of the collective plasmon modes of the metal shell. We use finite-difference time domain calculations on silica colloids with a core diameter of 456 nm, surrounded by a 38 nm thick Au shell, to study the temporal evolution of the mode field intensity inside the cavity upon pulsed excitation. Calculations using Mie theory and the T-matrix method are used to analytically determine the dipolar cavity resonance spectrum, which is found superimposed on the broad collective dipolar plasmonic resonance modes. We characterize resonance wavelength and linewidth in terms of a geometric mode confined inside the cavity. Cavity linewidth can be controlled by metal shell thickness and quality factors Q Ͼ 150 are observed. Due to the small cavity mode volume V = 0.2͑ / n͒ 3 , a Purcell factor as high as P =54 is calculated. Introducing shape anisotropy lifts the cavity mode degeneracy, yielding blue-and redshifted longitudinal and transverse resonant modes, respectively. The relatively large volume over which the field enhancement is observed in these spherical and anisotropic metal shell cavities, combined with cavity quality factors that are much higher than that of the collective plasmonic modes, makes them attractive for application in nanoscale light sources, sensors, or lasers.

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Spectroscopic properties of a two-level atom interacting with a complex spherical nanoshell

Cited by 39 publications

References 61 publications

Non-radiative decay of a dipole emitter close to a metallic nanoparticle: Importance of higher-order multipole contributions

Non-radiative decay of a dipole emitter close to a metallic nanoparticle: Importance of higher-order multipole contributions

Electromagnetic energy in multilayered spherical particles

Optical cavity modes in gold shell colloids

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