Nanoscale quantum dot infrared sensors with photonic crystal cavity

Posani, K. T.; Tripathi, V.K.; Annamalai, Senthil; Weisse-Bernstein, N.; Krishna, S.; Perahia, R.; Crisafulli, Orion; Painter, Oskar

doi:10.1063/1.2194167

Cited by 95 publications

(40 citation statements)

References 20 publications

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“…For example, photon tunneling in coupled photonic crystal nanocavities (PCNs) is governed by the electric LDOS spatial overlap between neighboring resonators 8 . Similarly, the electric LDOS of a localized mode strongly influences the light-matter interaction of a single quantum emitter (being directly related to the spontaneous emission rate 9 as well as to the signal amplification 10 ), and the electric LDOS is crucial for the development of efficient sensors 11,12 . Major advances in tailoring the electric LDOS at the nanoscale have led, on one hand, to a sub-wavelength electric field confinement in metallic nanoantennas to control the directional emission 13 and, on the other hand, to the achievement of the strong coupling regime, with the requirement of placing the wavelength-matched nano-emitter at the location of the maximum of the PCN electric LDOS at a spatial precision of approximately l/15 14 .…”

Section: Introductionmentioning

confidence: 99%

Ultra-subwavelength phase-sensitive Fano-imaging of localized photonic modes

et al. 2015

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Photonic and plasmonic devices rely on nanoscale control of the local density of optical states (LDOS) in dielectric and metallic environments. The tremendous progress in designing and tailoring the electric LDOS of nano-resonators requires an investigation tool that is able to access the detailed features of the optical localized resonant modes with deep-subwavelength spatial resolution. This scenario has motivated the development of different nanoscale imaging techniques. Here, we prove that a technique involving the combination of scanning near-field optical microscopy with resonant scattering spectroscopy enables imaging the electric LDOS in nano-resonators with outstanding spatial resolution (l/19) by means of a pure optical method based on light scattering. Using this technique, we investigate the properties of photonic crystal nanocavities, demonstrating that the resonant modes appear as characteristic Fano line shapes, which arise from interference. Therefore, by monitoring the spatial variation of the Fano line shape, we locally measure the phase modulation of the resonant modes without the need of external heterodyne detection. This novel, deep-subwavelength imaging method allows us to access both the intensity and the phase modulation of localized electric fields. Finally, this technique could be implemented on any type of platform, being particularly appealing for those based on non-optically active material, such as silicon, glass, polymers, or metals.

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Section: Introductionmentioning

confidence: 99%

Ultra-subwavelength phase-sensitive Fano-imaging of localized photonic modes

et al. 2015

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“…Most of the work so far has been focused on the absorption change in one-dimensional distributed Bragg reflector (1D DBR) based cavities [12,20], or one-, two-and three-dimensional (1D, 2D, 3D) metallic photonic crystal cavities [11,13,17]. Little work has been reported on the modified absorption characteristics in 2D dielectric photonic crystal slab (PCS) cavities [14], to the best of our knowledge.…”

Section: Introductionmentioning

confidence: 99%

“…Enhanced absorption can happen near or at the band edge where the electromagnetic Bloch wave is still extended throughout the structure, its group velocity is near zero, and the photonic DOS is greatly increased. In this regime, enhanced light-matter interaction is expected, and enhanced laser gain, light absorption and nonlinear effects have all been proposed [2,[11][12][13][14][15][16][17]. Enhanced absorption in tungsten 3D PCs has been reported [18].…”

Section: Introductionmentioning

confidence: 99%

“…quantum well, quantum dots) can lead to the modification of the absorption characteristics, due to the spectrallyselective light-matter interaction in the cavity. We propose a photonic crystal infrared Page 2 photodetector (PCIP) configuration, where the photonic crystal defect cavity was integrated with the quantum dot infrared photodetectors (QDIPs) [14,21] for higher operation temperature and spectrally selective absorption, highly desirable for infrared gas sensing and hyper-spectral imaging. High spectral selectivity with tunable wavelength coverage and spectral width can be feasible based on defect engineering and simple lithographic control, and/or external control [22].…”

Section: Introductionmentioning

confidence: 99%

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Spectrally selective infrared absorption in defect-mode photonic-crystal-slab cavity

et al. 2007

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Abstract.Significantly enhanced absorption at the defect mode can be obtained at surfacenormal direction in a dielectric single-defect photonic-crystal-slab, with an absorption enhancement factor greater than 4,000. Complete absorption suppression within the photonic bandgap region can also be observed in defect-free photonic crystal cavities. High spectral selectivity and tunability is feasible with defect mode engineering, making photonic crystal defect cavities a promising nanophotonic platform for the spectrally selective infrared sensing and hyper-spectral imaging, with the incorporation of quantum well or quantum dot infrared photodetector heterostructures.

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“…It is assumed that the QDIP active region is lightly doped by donors. The quantum−dot infrared photo− detector has emerged as an interesting and potentially viable device, wherein three−dimensional quantum confinement promises low dark currents [12,13], leading to a large detec− tivity [7]. We focus on QDIPs with multiple QD arrays of large−size QDs.…”

Section: Device Structure and Operational Principlementioning

confidence: 99%

Comparison studies of infrared photodetectors with a quantum-dot and a quantum-wire base

El_Tokhy

Mahmoud

Konber

2011

Opto-Electronics Review

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This paper mainly presents a theoretical analysis for the characteristics of quantum dot infrared photodetectors (QDIPs) and quantum wire infrared photodetectors (QRIPs). The paper introduces a unique mathematical model of solving Poisson’s equations with the usage of Lambert W functions for infrared detectors’ structures based on quantum effects. Even though QRIPs and QDIPs have been the subject of extensive researches and development during the past decade, it is still essential to implement theoretical models allowing to estimate the ultimate performance of those detectors such as photocurrent and its figure-of-merit detectivity vs. various parameter conditions such as applied voltage, number of quantum wire layers, quantum dot layers, lateral characteristic size, doping density, operation temperature, and structural parameters of the quantum dots (QDs), and quantum wires (QRs). A comparison is made between the computed results of the implemented models and fine agreements are observed. It is concluded from the obtained results that the total detectivity of QDIPs can be significantly lower than that in the QRIPs and main features of the QRIPs such as large gap between the induced photocurrent and dark current of QRIP which allows for overcoming the problems in the QDIPs. This confirms what is evaluated before in the literature. It is evident that by increasing the QD/QR absorption volume in QDIPs/QRIPs as well as by separating the dark current and photocurrents, the specific detectivity can be improved and consequently the devices can operate at higher temperatures. It is an interesting result and it may be benefit to the development of QDIP and QRIP for infrared sensing applications.

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Nanoscale quantum dot infrared sensors with photonic crystal cavity

Cited by 95 publications

References 20 publications

Ultra-subwavelength phase-sensitive Fano-imaging of localized photonic modes

Ultra-subwavelength phase-sensitive Fano-imaging of localized photonic modes

Spectrally selective infrared absorption in defect-mode photonic-crystal-slab cavity

Comparison studies of infrared photodetectors with a quantum-dot and a quantum-wire base

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