Description of dispersion properties of metals by means of the critical points model and application to the study of resonant structures using the FDTD method

Vial, Alexandre; Laroche, Thierry

doi:10.1088/0022-3727/40/22/043

Cited by 156 publications

(107 citation statements)

References 25 publications

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“…is used to stick gold on substrate. This adhesion layer is usually neglected in simulations, excepted in a few studies for Surface Plasmon Resonance based biosensor [3,6,7], and in the case of cylinder-based transducer [42]. Nevertheless in the theoretical and numerical studies, the roughness of the gold nanostructures are neglected and the nanometric adhesion layer of gold on substrate is rarely included.…”

Section: Introductionmentioning

confidence: 99%

“…This chapter is dedicated to the parametric study of a specific nanobiosensor, made of a grating of gold nanocylinders deposited on a dielectric substrate and the goal is to investigate the influence of adhesion layer and roughness on the position of the LSPR as a function of the geometrical parameters of cylinders: their diameter D and height h. The first section is devoted to the validation of the model by comparison to previous simulations with Finite Difference Time Domain [42], and to experimental results [20,21,23]. The analysis of the parametric study is given in section 3 and a method to deduce heuristic laws for the LSPR is also proposed, before concluding.…”

Section: Introductionmentioning

confidence: 99%

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Nanostructured Biosensors: Influence of Adhesion Layer, Roughness and Size on the LSPR: A Parametric Study

Kessentini¹,

Barchiesi²

2013

State of the Art in Biosensors - General Aspects

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nanostructured Biosensors: Influence of Adhesion Layer, Roughness and Size on the LSPR: A Parametric Study

Kessentini¹,

Barchiesi²

2013

State of the Art in Biosensors - General Aspects

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“…Probes aligned to the central, vertical axis of each antenna were place at 5 nm above and 6 nm inside each structure to capture and respectively. Each simulation was performed with a FDTD solver, and the optical properties of the metal were fit to the Drude model 31 . The heat source density was found by inputting the calculated electric field at the specified probe location into the following equation,…”

mentioning

confidence: 99%

Probing and Controlling Photothermal Heat Generation in Plasmonic Nanostructures

et al. 2013

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In the emerging field of thermoplasmonics, Joule heating associated with optically resonant plasmonic structures is exploited to generate nanoscale thermal hotspots.In the present study, new methods for designing and thermally probing thermoplasmonic structures are reported. A general design rationale, based on Babinet's principle, is developed for understanding how the complementary version of ideal electromagnetic antennae can yield efficient nanoscale heat sources with maximized current density. Using this methodology, we show that the diabolo antenna is more suitable for heat generation compared with its more well-known complementary structure, the bow-tie antenna. We also demonstrate that highly localized and enhanced thermal hot spots can be realized by incorporating the diabolo antenna into a plasmonic lens. Using a newly developed thermal microscopy method based on the temperature-dependent photoluminescence lifetime of thin-film thermographic phosphors, we experimentally characterize the thermal response of various antenna and superstructure designs. Data from FDTD simulations and the experimental temperature measurements confirm the validity of the design rationale. The thermal microscopy technique, with its robust sensing method, could overcome some of the drawbacks of current micro/nanoscale temperature measurement schemes.

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“…The Drude model is a poor approximation for metals in this frequency range, and here we use a fit based on measured data 48 for the permittivity, utilizing an augmented Drude model. 49 Figure 9(a) shows the surface impedance for three different thickness values (t) of the metal (here t = d is fixed and is not the skin depth as used for the THz calculations), with the corresponding transmissivity shown in Fig. 9(b) for a five-layer structure, where D = 100 nm, g = 10 nm, h = 166 nm, and r = 1 (results were computed using the transfer-matrix approach).…”

Section: Resultsmentioning

confidence: 99%

Dual capacitive-inductive nature of periodic graphene patches: Transmission characteristics at low-terahertz frequencies

et al. 2013

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We report on the dual nature (capacitive and inductive) of the surface impedance of periodic graphene patches at low-terahertz frequencies. The transmission spectra of a graphene-dielectric stack shows that patterned graphene exhibits both the low-frequency (capacitive) passband of metal patch arrays and the higher-frequency (inductive) passband of metal aperture arrays in a single tunable configuration. The analysis is carried out using a transfer-matrix approach with two-sided impedance boundary conditions, and the results are verified using full-wave numerical simulations. In addition, the Bloch-wave analysis of the corresponding infinite periodic structure is presented in order to explain the passband and stopband characteristics of the finite graphene-dielectric stack.

show abstract

Description of dispersion properties of metals by means of the critical points model and application to the study of resonant structures using the FDTD method

Cited by 156 publications

References 25 publications

Nanostructured Biosensors: Influence of Adhesion Layer, Roughness and Size on the LSPR: A Parametric Study

Nanostructured Biosensors: Influence of Adhesion Layer, Roughness and Size on the LSPR: A Parametric Study

Probing and Controlling Photothermal Heat Generation in Plasmonic Nanostructures

Dual capacitive-inductive nature of periodic graphene patches: Transmission characteristics at low-terahertz frequencies

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