All-epitaxial long-range surface plasmon polariton structures with integrated active materials

Nordin, Leland; Petluru, Priyanka; Muhowski, Aaron J.; Shaner, Eric A.; Wasserman, D.

doi:10.1063/5.0041509

Cited by 6 publications

(5 citation statements)

References 45 publications

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“…11 Operating regimes of graphene plasmonic field-effect transistors (FETs) are proposed by Zhang and Shur. 12 The unidirectional propagation of SPP waves in a nanolaser based on a graphene-insulator-metal (GIM) platform paves the way for the future development of plasmonic circuitry using GIM platforms that can perform fast signal modulation and processing according to the recent results discussed by Li et al 13 All-epitaxial structures consisting of type-II superlattice materials quantum engineered by sandwiching a heavily doped semiconductor layer acting as plasmonic thin film are demonstrated by Nordin et al 14 to support short-and long-range surface plasmon polariton (SRSPP and LRSPP) modes in the long-wave infrared region of the electromagnetic spectrum.…”

Section: Journal Of Applied Physicsmentioning

confidence: 98%

Plasmonics: Enabling functionalities with novel materials

Losurdo

Moreno

Cobet

et al. 2021

Journal of Applied Physics

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Section: Journal Of Applied Physicsmentioning

confidence: 98%

Plasmonics: Enabling functionalities with novel materials

Losurdo

Moreno

Cobet

et al. 2021

Journal of Applied Physics

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“…See the supplementary material for x-ray diffraction measurements of as-grown device material. 33 The first three generations of plasmonic detectors (T max = 170, 185, 195K) used superlattice absorbers with decreasing period (40, 35, 30 ML) and superlattice (SL) barriers. Decreasing the absorber SL period blue-shifts the effective bandgap (as seen in the λ 1%EQE max column), with little to no effect on the position of the absorption peak, and subsequent position of λ 50% EQE max .…”

Section: Supplementary Materialsmentioning

confidence: 99%

“…The demonstrated detectors highlight only one of a range of optical designs incorporating integrated plasmonic layers. There exists considerable potential for LWIR detector architectures with enhanced functionality, such as ultra-fast detection, or spectrally tunable/switchable detection which could be enabled by different plasmonic optoelectronic architectures 33 . The detectors demonstrated here are thus an important step towards room temperature devices, as well as device architectures with the potential to extend the limits of LWIR detection and detector functionality.…”

mentioning

confidence: 99%

High operating temperature plasmonic infrared detectors

Nordin,

Muhowski,

Wasserman

2022

Preprint

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III-V semiconductor type-II superlattices (T2SLs) are a promising material system with the potential to significantly reduce the dark current of, and thus realize high-performance in, infrared photodetectors at elevated temperatures. However, T2SLs have struggled to meet the performance metrics set by the longstanding infrared detector material of choice, HgCdTe. Recently, epitaxial plasmonic detector architectures have demonstrated T2SL detector performance comparable to HgCdTe in the 77 K -195 K temperature range. Here we demonstrate a high operating temperature plasmonic T2SL detector architecture with high-performance operation at temperatures accessible with two-stage thermoelectric coolers. Specifically, we demonstrate long-wave infrared plasmonic detectors operating at temperatures as high as 230 K while maintaining dark currents below the "Rule 07" heuristic. At a detector operating temperature of 230 K, we realize 22.8% external quantum efficiency in a detector absorber only 372 nm thick (∼ λ 0 /25) with peak specific detectivity of 2.29 × 10 9 cmHz 1/2 W −1 at 9.6 µm, well above commercial detectors at the same operating temperature.

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“…InAs/GaSb Type II Superlattice (T2SL) on GaSb substrate has emerged as a potential photodetector material, offering high performance by exceptional quantum efficiency and low dark current levels, which enables state-of-art infrared detection by controlling the band gap of an InAs/GaSb T2SL 16 , 17 . Coupling a detector with resonant structures such as Fabry–Perot 18 , 19 and surface plasmon modes 20 offer both resonant and broadband enhancement, which enables the encoding of spectral and polarization information, significantly enhancing the detector's signal-to-noise characteristics 21 – 26 .…”

Section: Introductionmentioning

confidence: 99%

Simulational investigation of self-aligned bilayer linear grating enabling highly enhanced responsivity of MWIR InAs/GaSb type-II superlattice (T2SL) photodetector

Lee,

Ku,

Jeong

et al. 2024

Sci Rep

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Linear gratings polarizers provide remarkable potential to customize the polarization properties and tailor device functionality via dimensional tuning of configurations. Here, we extensively investigate the polarization properties of single- and double-layer linear grating, mainly focusing on self-aligned bilayer linear grating (SABLG), serving as a wire grid polarizer in the mid-wavelength infrared (MWIR) region. Computational analyses revealed the polarization properties of SABLG, highlighting enhancement in TM transmission and reduction in TE transmission compared to single-layer linear gratings (SLG) due to optical cavity effects. As a result, the extinction ratio is enhanced by approximately 2724-fold in wavelength 3–6 μm. Furthermore, integrating the specially designed SABLG with an MWIR InAs/GaSb Type-II Superlattice (T2SL) photodetector yields a significantly enhanced spectral responsivity. The TM-spectral responsivity of SABLG is enhanced by around twofold than the bare device. The simulation methodology and analytical analysis presented herein provide a versatile route for designing optimized polarimetric structures integrated into infrared imaging devices, offering superior capabilities to resolve linear polarization signatures.

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All-epitaxial long-range surface plasmon polariton structures with integrated active materials

Cited by 6 publications

References 45 publications

Plasmonics: Enabling functionalities with novel materials

Plasmonics: Enabling functionalities with novel materials

High operating temperature plasmonic infrared detectors

Simulational investigation of self-aligned bilayer linear grating enabling highly enhanced responsivity of MWIR InAs/GaSb type-II superlattice (T2SL) photodetector

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