Ultra-thin plasmonic detectors

Nordin, Leland; Petluru, Priyanka; Kamboj, Abhilasha; Muhowski, Aaron J.; Wasserman, D.

doi:10.1364/optica.438039

Cited by 33 publications

(25 citation statements)

References 39 publications

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“…Moreover, MCT materials are facing increased restrictions, including being banned in European markets, due to environmental concerns associated with mercury and cadmium 2 . For this reason there has been historical, and increasing, interest in developing alternative materials and architectures, specifically in the III-V semiconductor family, for LWIR detection 1,3 .…”

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confidence: 99%

“…The current and long-time stateof-the-art LWIR detector is the HgCdTe (MCT) photodetector. MCT detectors, in addition to suffering the same hightemperature challenges as any LWIR detector, rely on the epitaxial growth of II-VI alloys, for which uniform growth is notoriously difficult, especially for the high Hg-content HgCdTe alloys required for LWIR detection 1 . Moreover, MCT materials are facing increased restrictions, including being banned in European markets, due to environmental concerns associated with mercury and cadmium 2 .…”

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confidence: 99%

“…However, T2SL detectors have struggled to meet predicted performance metrics, in part a result of short minority carrier lifetimes 6 and/or low absorption coefficients 7 . One increasingly attractive approach to overcoming the poorer performance of T2SL-based detectors has been to leverage detector architectures which enhance the optical fields in the detector [8][9][10][11][12][13][14][15][16] to increase detector absorption while maintaining small detector volumes, and therefore low a) Author to whom correspondence should be addressed: nordin@utexas.edu dark currents.…”

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confidence: 99%

“…A particularly successful implementation of opticallyenhanced T2SL detectors is the recently-demonstrated ultrathin (t ∼ λ 0 /30) plasmonic detector 15 , which realizes responsivities commensurate with much thicker traditional detectors (t ∼ λ 0 ), while also demonstrating dark currents substantially below "Rule 07" 17 , the heuristic for HgCdTe detectors and thus a useful benchmark for competing detector technologies. In such an architecture, an ultra-thin (∼ 311 nm) T2SL detector structure is grown upon a heavily (n ++ ) doped semiconductor 'ground-plane'.…”

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confidence: 99%

“…Figure 1(b) shows rigorous coupled wave analysis 20 (RCWA) simulations of plasmonic detector external quantum efficiency (EQE) for absorber cutoff wavelengths from 9 µm to 14 µm. For these simulations, we use a complex uniaxial permittivity tensor for the T2SL 21 with ε || obtained from our previous work 15 and ε ⊥ = 12.56. As can be seen in Fig.…”

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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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confidence: 99%

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confidence: 99%

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confidence: 99%

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High operating temperature plasmonic infrared detectors

Nordin,

Muhowski,

Wasserman

2022

Preprint

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Simultaneous Control of Spectral And Directional Emissivity with Gradient Epsilon‐Near‐Zero InAs Photonic Structures

2023

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Controlling both the spectral bandwidth and directionality of emitted thermal radiation is a fundamental challenge in contemporary photonics. Recent work has shown that materials with a spatial gradient in the frequency range of their epsilon‐near‐zero (ENZ) response can support broad spectrum directionality in their emissivity, enabling high total radiance to specific angles of incidence. However, this capability is limited spectrally and directionally by the availability of materials with phonon‐polariton resonances over long‐wave infrared wavelengths. Here, an approach is designed and experimentally demonstrated using doped III–V semiconductors that can simultaneously tailor spectral peak, bandwidth, and directionality of infrared emissivity. InAs‐based gradient ENZ photonic structures that exhibit broadband directional emission with varying spectral bandwidths and directional ranges as a function of their doping concentration profile and thickness are epitaxially grown and characterized. Due to its easy‐to‐fabricate geometry, it is believed that this approach provides a versatile photonic platform to dynamically control broadband spectral and directional emissivity for a range of emerging applications in heat transfer and infrared sensing.

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Plasmonic Tunnel Diode and Photodetector based on Layer‐Stacked AuNP‐Nanomembrane/p‐Si Heterojunction

Jin

2022

Adv Elect Materials

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Researches based on conceptual plasmoelectric devices such as photodetectors, [3] photovoltaic devices, [4] and plasmonic tunneling junction memristors, [5] have been found to have some unusual electron transport properties [6,7] of the materials and devices. In such devices, plasmons and electromagnetic field enhancement can be driven either by optical illumination or electrically. The optically excited plasmons mode usually couples with the incident light to transfer the energy of localized surface plasmon resonance (LSPR) to carriers directly by plasmons decay nonradiatively; [8] while electrically driven plasmons, as recently been diversely demonstrated, require efficient nanoscale integration of electrical and optical circuits and optoelectronic conversion which influence carriers dynamics by exciting plasmonic fields based on special plasmonic nanomaterials. [9,10] Diodes with unidirectional rectifying behavior are important components of modern electronic devices such as integrated circuits, photodetectors, and luminescent devices, etc. Basically, rectification behavior occurs at asymmetric interfaces such as p-n junctions or metal/ semiconductor interfaces with Schottky barriers, [11,12] where diverse plasmonic metal nanostructure/semiconductor hybrid heterojunctions can be introduced to enhance the efficiency of electrons transport and photoexcitation through subwavelength optical manipulation. [13,14] Although the metal/semiconductor heterojunction-based devices with plasmonic subwavelength optoelectronic properties have been reported for energy conversion study, [15][16][17] no attempts were reported so far on manipulating plasmoelectronic property of plasmonic nanostructures at the metal/semiconductor interfaces for potential diode applications. Moreover, recently diodes based on 2D materials (graphene, MXene, and transition metal dichalcogenides, etc.) have aroused increasing interest due to their giant potentials to surpass Moore's law. [18,19] Therefore, 2D plasmonic nano materials with symmetric and integrated subwavelength structures aroused our attention as they showed higher light-harvesting efficiency and electromagnetic field enhancements (achieved more easily over large areas in 2D plasmonic nanostructures) than their 1D counterparts. [20][21][22] Recently, we and others have revealed some interesting phenomenon and properties of electrons transport based on 2D plasmonic nano membrane, such as plasmon-enabled long-range electron tunneling Electronic devices with rectifying effect are typical building blocks for integrated circuits and useful for photodetectors. Herein, a new type of diode based on plasmonic tunnel hetero-nanostructure is reported. By constructing a planar plasmoelectric junction between p-Si and Au pad electrode with a few-layer-stacked 2D plasmonic AuNP-nanomembrane as a medium layer, rectifying behavior of the device is achieved, though the direct contact between bulk Au and semiconductor usually tends to form ohmic contact. The electrically driven plasmons enable the 2D A...

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Ultra-thin plasmonic detectors

Cited by 33 publications

References 39 publications

High operating temperature plasmonic infrared detectors

High operating temperature plasmonic infrared detectors

Simultaneous Control of Spectral And Directional Emissivity with Gradient Epsilon‐Near‐Zero InAs Photonic Structures

Plasmonic Tunnel Diode and Photodetector based on Layer‐Stacked AuNP‐Nanomembrane/p‐Si Heterojunction

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