Ge-on-Si Single-Photon Avalanche Diode Detectors: Design, Modeling, Fabrication, and Characterization at Wavelengths 1310 and 1550 nm

Warburton, R. J.; Intermite, Giuseppe; Myronov, Maksym; Allred, Phil; Leadley, D. R.; Gallacher, Kevin; Paul, Douglas J.; Pilgrim, N. J.; Lever, L.; Ikonić, Z.; Kelsall, R. W.; Huante-Ceron, Edgar; Knights, Andrew P.; Buller, Gerald S.

doi:10.1109/ted.2013.2282712

Cited by 79 publications

(79 citation statements)

References 31 publications

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“…Following the refinement of the seed layer approach to Ge absorption layer/Si multiplication layer SPADs, there have been several experimental demonstrations of this structure. In 2013, Warburton et al demonstrated the lowest reported (to date) noise-equivalent power for a thick Ge-on-Si SPAD at 1 Â 10 À14 WHz À½ at a wavelength of 1.31 μm [66]. The structure of this device is shown in Fig.…”

Section: à16mentioning

confidence: 94%

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Single-Photon Detectors for Infrared Wavelengths in the Range 1–1.7 μm

Buller¹,

Collins²

2014

Springer Series on Fluorescence

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The ongoing progress of scientific research in areas such as quantum communications, low-light level laser ranging, and material science (to name but a few) has led to increased interest in the detection of single photons in the wavelength range 1-1.7 μm. Several technologies have been used to detect photons with wavelengths in this range -each with different characteristic parameters that affect their suitability for specific applications. This chapter will provide a review of progress in the development of detectors for use in this spectral region and will highlight some notable results.

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Section: à16mentioning

confidence: 94%

“…6 A cross section through the 25 μm diameter circular mesa structure of a germanium on silicon (Ge-on-Si) single-photon avalanche diode (SPAD) [66]. The Ni/Al layer forms the top contacts and Si3N4 is used for passivation and insulation (heterostructures) with the same crystal axis [74].…”

Section: Quantum Dot-based Detectorsmentioning

confidence: 99%

Single-Photon Detectors for Infrared Wavelengths in the Range 1–1.7 μm

Buller¹,

Collins²

2014

Springer Series on Fluorescence

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“…There is hope, though, that one day a detector such as the vertically coupled germanium APD demonstrated by Warburton et al [75] (shown in Figs. 8c and 8d) could fill the role, with sufficient performance.…”

Section: Single-photon Detectorsmentioning

confidence: 99%

“…A batch of SNSPDs is fabricated on a Si 3 N 4 membrane, selected based on performance, and transferred onto a silicon waveguide for use. c. Cross-section view of a vertically-coupled germanium avalanche photodiode from[75], and d. electron micrograph of the fabricated device. Image credit: N. C. Harris, G. S. Buller.…”

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confidence: 99%

Silicon Quantum Photonics

Silverstone

Bonneau

O’Brien

et al. 2016

IEEE J. Select. Topics Quantum Electron.

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194

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Integrated quantum photonic applications, providing physially guaranteed communications security, sub-shot-noise measurement, and tremendous computational power, are nearly within technological reach. Silicon as a technology platform has proven formibable in establishing the micro-electornics revoltution, and it might do so again in the quantum technology revolution. Silicon has has taken photonics by storm, with its promise of scalable manufacture, integration, and compatibility with CMOS microelectronics. These same properties, and a few others, motivate its use for large-scale quantum optics as well. In this article we provide context to the development of quantum optics in silicon. We review the development of the various components which constitute integrated quantum photonic systems, and we identify the challenges which must be faced and their potential solutions for silicon quantum photonics to make quantum technology a reality

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“…It has a direct bandgap (Γ-valley) which is only 140 meV larger than the indirect bandgap, allowing for the potential of emitters such as lasers [3,4] and LEDs [5], as well as waveguides [6], photodetec-tors [7,8], and modulators [9,10], all on a Si platform. With high degenerate n-type doping the Fermi level can be moved near to the Γ-valley, resulting in either optically or electrically injected carriers having a higher probability of recombining radiatively at this band; both electrically and optically pumped Ge lasers have been demonstrated by this technique [3,4].…”

Section: Introductionmentioning

confidence: 99%

Extending the emission wavelength of Ge nanopillars to 225 μm using silicon nitride stressors

Millar¹,

Gallacher²,

Samarelli³

et al. 2015

Opt. Express

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Abstract:The room temperature photoluminescence from Ge nanopillars has been extended from 1.6 μm to above 2.25 μm wavelength through the application of tensile stress from silicon nitride stressors deposited by inductively-coupled-plasma plasma-enhanced chemical-vapour-deposition. Photoluminescence measurements demonstrate biaxial equivalent tensile strains of up to ∼ 1.35% in square topped nanopillars with side lengths of 200 nm. Biaxial equivalent strains of 0.9% are observed in 300 nm square top pillars, confirmed by confocal Raman spectroscopy. Finite element modelling demonstrates that an all-around stressor layer is preferable to a top only stressor, as it increases the hydrostatic component of the strain, leading to an increased shift in the band-edge and improved uniformity over top-surface only stressors layers. Bridging the gap between theory and experiment," J. Appl. Phys. 79, 7148-7156 (1996).

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Ge-on-Si Single-Photon Avalanche Diode Detectors: Design, Modeling, Fabrication, and Characterization at Wavelengths 1310 and 1550 nm

Cited by 79 publications

References 31 publications

Single-Photon Detectors for Infrared Wavelengths in the Range 1–1.7 μm

Single-Photon Detectors for Infrared Wavelengths in the Range 1–1.7 μm

Silicon Quantum Photonics

Extending the emission wavelength of Ge nanopillars to 225 μm using silicon nitride stressors

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