2016
DOI: 10.1007/978-981-10-2021-6_4
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Plasmonic Entities within the Charge Transporting Layer

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Cited by 3 publications
(9 citation statements)
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“…The metal NP behaves as an electric dipole under a uniform static electric field assumption, and its polarizability, α(λ), is derived as:α(λ)=4sans-serifπr3ε(λ)εd(λ)ε(λ)+2εd(λ) When ε(λ)2εd(λ), the dominator of Equation (2) approaches zero and yields maximum polarization: in order to achieve this condition, the dielectric function (real part) ε(λ) of the NP requires a negative value, where the dielectric function of the surrounding medium is considered as a constant, and the losses (imaginary part) of the NP are assumed to be small [11]. Using the Drude model, the resonance frequency (ωLSP) of a dipolar LSP can be given by [12]:ωLSP=ωp1+εd where ωp is the plasmon frequency of the NP’s material. At the resonance frequency, as shown in Figure 1, the free electrons moved away from their equilibrium p...…”
Section: Localized Surface Plasmon Resonance Sensormentioning
confidence: 99%
“…The metal NP behaves as an electric dipole under a uniform static electric field assumption, and its polarizability, α(λ), is derived as:α(λ)=4sans-serifπr3ε(λ)εd(λ)ε(λ)+2εd(λ) When ε(λ)2εd(λ), the dominator of Equation (2) approaches zero and yields maximum polarization: in order to achieve this condition, the dielectric function (real part) ε(λ) of the NP requires a negative value, where the dielectric function of the surrounding medium is considered as a constant, and the losses (imaginary part) of the NP are assumed to be small [11]. Using the Drude model, the resonance frequency (ωLSP) of a dipolar LSP can be given by [12]:ωLSP=ωp1+εd where ωp is the plasmon frequency of the NP’s material. At the resonance frequency, as shown in Figure 1, the free electrons moved away from their equilibrium p...…”
Section: Localized Surface Plasmon Resonance Sensormentioning
confidence: 99%
“…Simulation of plasmonic SC is one case where the FDTD method has proven its ability to simulate the near and far-field and SPP effects [ 35 ]. Plasmonic SC mainly refers to the use of plasmonic NS to overcome the limitations of third-generation SCs such as OSC and perovskite cells [ 21 , 37 ]. Initially, more attention was paid to the light trapping due to the plasmonic NSs.…”
Section: Theory and Modelingmentioning
confidence: 99%
“…MNSs with various sizes and morphologies have been generally used in photovoltaics to activate plasmonic consequences [ 21 ]. Depending on their position inside OPV, it usually leads to three conventional optical mechanisms, namely (1) light scattering, (2) LSPR, (3) surface plasmon polaritons (SPPs).…”
Section: Introductionmentioning
confidence: 99%
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