Resonant absorption in semiconductor nanowires and nanowire arrays: Relating leaky waveguide modes to Bloch photonic crystal modes

Fountaine, Katherine T.; Whitney, William S.; Atwater, Harry A.

doi:10.1063/1.4898758

Cited by 108 publications

(118 citation statements)

References 31 publications

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“…In fact, broad band and broad angle absorption is expected for the lowest m = 1 Mie resonances (HE 11 mode) shown therein, indeed occurring for both TM-and TE-polarized light (see Figure 6c,d), being stronger at normal incidence for TM polarization. 28 In addition, Figure 6d reveals that the TM 01 leaky mode band lies, as mentioned in the preceding section, close to the m = 0 TM Mie resonance at large oblique angles, which yields a large absorption area at ∼2.5 eV (500 nm) near θ ≃ 70°, as a result in turn of the overlap with the m = 1 Mie band. In the low energy region below 2.5 eV, this m = 0 TM Mie resonance continues, as mentioned above, as a weak absorption band for smaller angles of incidence.…”

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confidence: 86%

Unraveling the Janus Role of Mie Resonances and Leaky/Guided Modes in Semiconductor Nanowire Absorption for Enhanced Light Harvesting

2015

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Light absorption from finite semiconductor nanowires is investigated through a unified theoretical picture and numerical simulations. We first show theoretically from the electromagnetic mode dispersion relation and the Mie extinction cross sections for infinite nanowires that formally equivalent (Janus) formulas yield both leaky/guided modes and Mie resonances as, respectively, complex wave vector or complex frequency solutions that, in turn, overlap only at grazing angles with respect to the nanowire axis. For finite semiconductor nanowires, the angle of incidence becomes critical: absorption is dominated by Mie resonances at incident angles perpendicular (and oblique) to the nanowire axis; by contrast, guided mode excitation (if spectrally available) governs and enhances absorption at grazing incidence. Such theoretical prediction can be exploited to optimize nanowire designs for broad band and broad angle light harvesting applications.

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confidence: 86%

Unraveling the Janus Role of Mie Resonances and Leaky/Guided Modes in Semiconductor Nanowire Absorption for Enhanced Light Harvesting

2015

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“…4,[19][20][21][22][23][24][25][26] The macroscopic optoelectronic and electrochemical properties of such wire arrays have been experimentally characterized [27][28][29][30][31] , but nanoscale analyses that aim to provide a microscopic understanding of these properties have been mostly limited to theoretical and computational methodologies. [32][33][34][35] The optical excitation of photoactive semiconductor substrates immersed in a metal-ion solution can provide the driving force for deposition of a metal. 36 Photoelectrochemical metal deposition has been used to generate arbitrarily patterned metallic deposits on a semiconductor surface by use of a photomask or by use of scanning laser illumination.…”

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confidence: 99%

Profiling Photoinduced Carrier Generation in Semiconductor Microwire Arrays via Photoelectrochemical Metal Deposition

et al. 2016

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Au was photoelectrochemically deposited onto cylindrical or tapered p-Si microwires on Si substrates to profile the photoinduced charge-carrier generation in individual wires in a photoactive semiconductor wire array. Similar experiments were repeated for otherwise identical Si microwires doped to be n-type. The metal plating profile was conformal for n-type wires, but for p-type wires was a function of distance from the substrate and was dependent on the illumination wavelength. Spatially resolved charge-carrier generation profiles were computed using full-wave electromagnetic simulations, and the localization of the deposition at the p-type wire surfaces observed experimentally correlated well with the regions of enhanced calculated carrier generation in the volumes of the microwires. This technique could potentially be extended to determine the spatially resolved carrier generation profiles in a variety of mesostructured, photoactive semiconductors.

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“…For consistency, these material setup was also used for the electric field distribution calculations. 19 The band diagram of TE-polarized eigen-modes for SiNWs along Z direction is shown in Fig. 2(b).…”

Section: Discussionmentioning

confidence: 99%

“…Under band calculation, Bloch boundary conditions are applied to SiNWs along X, Y and Z direction. 19 Although the length of SiNWs along Z direction should be regarded as infinite, it is deliberately given a period of 1a to obtain the Bloch wave vector k z within the reduced Brilloiin zone, from 0 to 0.5 (2π/a). A wide band Gaussian wave with E x polarization was randomly positioned in the SiNWs to excite arbitrary eigen-modes.…”

Section: Discussionmentioning

confidence: 99%

Broadband light absorption of silicon nanowires embedded in Ag nano-hole arrays

Rao

2016

AIP Advances

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Silicon nanowires (SiNWs) embedded in Ag nano-hole arrays with broadband light absorption is proposed in this paper. Finite Difference Time Domain (FDTD) simulations were utilized to obtain absorptivity and band diagrams for both SiNWs and SiNWs embedded in Ag nano-hole arrays. A direct relationship between waveguide modes and extraordinary absorptivity is established qualitatively, which helps to optimal design the structure parameters to achieve broadband absorptivity. After introducing Ag nano-hole arrays at the rear side of SiNWs, the band modes are extended into leaky regions and light energy can be fully absorbed, resulting in high absorptivity at long wavelength. Severe reflection is also suppressed by light trapping capability of SiNWs at short wavelength. Over 70% average absorptivity from 400 nm to 1100 nm is realized finally. This kinds of design give promising route for high efficiency solar cells and optical absorbers.

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Resonant absorption in semiconductor nanowires and nanowire arrays: Relating leaky waveguide modes to Bloch photonic crystal modes

Cited by 108 publications

References 31 publications

Unraveling the Janus Role of Mie Resonances and Leaky/Guided Modes in Semiconductor Nanowire Absorption for Enhanced Light Harvesting

Unraveling the Janus Role of Mie Resonances and Leaky/Guided Modes in Semiconductor Nanowire Absorption for Enhanced Light Harvesting

Profiling Photoinduced Carrier Generation in Semiconductor Microwire Arrays via Photoelectrochemical Metal Deposition

Broadband light absorption of silicon nanowires embedded in Ag nano-hole arrays

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