FDTD for plasmonics: Applications in enhanced Raman spectroscopy

Yang, Zhilin; Li, QianHong; Ruan, Fangxiong; Li, Zhipeng; Ren, Bin; Xu, Hongxing; Zhang, Tian

doi:10.1007/s11434-010-4044-0

Cited by 62 publications

(39 citation statements)

References 49 publications

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“…112,113 Calculations of luminescence from arbitrarily shaped particles instead rely on general-purpose numerical techniques, 114 most commonly time-domain methods, [115][116][117][118][119][120] and include studies of bowtie antennas, 121 nanostars, 122 conical tips, [123][124][125] dimers, 126 and thin films. 127 Frequency domain methods include finite-element, 128,129 boundary-element, 130 and discrete dipole approximation (DDA) [131][132][133][134] methods.…”

Section: Introductionmentioning

confidence: 99%

Fluctuating volume-current formulation of electromagnetic fluctuations in inhomogeneous media: Incandescence and luminescence in arbitrary geometries

et al. 2015

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We describe a fluctuating volume-current formulation of electromagnetic fluctuations that extends our recent work on heat exchange and Casimir interactions between arbitrarily shaped homogeneous bodies [Phys. Rev. B. 88, 054305] to situations involving incandescence and luminescence problems, including thermal radiation, heat transfer, Casimir forces, spontaneous emission, fluorescence, and Raman scattering, in inhomogeneous media. Unlike previous scattering formulations based on field and/or surface unknowns, our work exploits powerful techniques from the volume-integral equation (VIE) method, in which electromagnetic scattering is described in terms of volumetric, current unknowns throughout the bodies. The resulting trace formulas (boxed equations) involve products of well-studied VIE matrices and describe power and momentum transfer between objects with spatially varying material properties and fluctuation characteristics. We demonstrate that thanks to the low-rank properties of the associated matrices, these formulas are susceptible to fast-trace computations based on iterative methods, making practical calculations tractable. We apply our techniques to study thermal radiation, heat transfer, and fluorescence in complicated geometries, checking our method against established techniques best suited for homogeneous bodies as well as applying it to obtain predictions of radiation from complex bodies with spatially varying permittivities and/or temperature profiles.

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Section: Introductionmentioning

confidence: 99%

Fluctuating volume-current formulation of electromagnetic fluctuations in inhomogeneous media: Incandescence and luminescence in arbitrary geometries

et al. 2015

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“…The result of this fit is shown as a dash-dotted curve in Figure 1. Because of the above-mentioned deficiency of the Drude model and also instability of Fourier transform in the algorithm, the general Drude model modified by the Debye model [26], and the dispersion model (an extended version of the Debye model) [27] are utilized.…”

Section: Electromagnetic Equationsmentioning

confidence: 99%

“…Like dimers, FDTD simulation of a combination of three different sized silver nano-spheres with polarization parallel to the axis of the symmetry shows the maximum field enhancement of about 300 in hot spots [26].…”

Section: Nano-structuresmentioning

confidence: 99%

Developing LSPR Design Guidelines

Mortazavi¹,

Kouzani²,

Kaynak³

et al. 2012

PIER

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Abstract-Applications of localized surface plasmon resonance (LSPR) such as surface enhanced Raman scattering (SERS) devices, biosensors, and nano-optics are growing.Investigating and understanding of the parameters that affect the LSPR spectrum is important for the design and fabrication of LSPR devices. This paper studies different parameters, including geometrical structures and light attributes, which affect the LSPR spectrum properties such as plasmon wavelength and enhancement factor. The paper also proposes a number of rules that should be considered in the design and fabrication of LSPR devices.

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“…Examples of such methods are the Green's tensor method with volume integral equation [18][19][20][21], boundary integral method [22], finitedifference time domain [23], discrete-dipole approximation [24], and finite integration technique [25].…”

Section: Numerical Modelmentioning

confidence: 99%

Bowtie Nanoantennas With Polynomial Sides in the Excitation and Emission Regimes

Costa¹,

Dmitriev²

2011

PIER B

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Abstract-In this work, we analyze modified bowtie nanoantennas with polynomial sides in the excitation and emission regimes. In the excitation regime, the antennas are illuminated by an incident plane wave, and in the emission regime, the excitation is fulfilled by infinitesimal electric dipole positioned in the gap of the nanoantennas. Several antennas with different sizes and polynomial order were numerically analyzed by method of moments. The results show that these novel antennas possess a controllable resonance by the polynomial order and good characteristics of near field enhancement and confinement for applications in enhancement of spontaneous emission of a single molecule.

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FDTD for plasmonics: Applications in enhanced Raman spectroscopy

Cited by 62 publications

References 49 publications

Fluctuating volume-current formulation of electromagnetic fluctuations in inhomogeneous media: Incandescence and luminescence in arbitrary geometries

Fluctuating volume-current formulation of electromagnetic fluctuations in inhomogeneous media: Incandescence and luminescence in arbitrary geometries

Developing LSPR Design Guidelines

Bowtie Nanoantennas With Polynomial Sides in the Excitation and Emission Regimes

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