A.L. Lacaita scite author profile

Avalanche photodiodes, which operate above the breakdown voltage in Geiger mode connected with avalanche-quenching circuits, can be used to detect single photons and are therefore called singlephoton avalanche diodes SPAD's. Circuit configurations suitable for this operation mode are critically analyzed and their relative merits in photon counting and timing applications are assessed. Simple passive-quenching circuits (PQC's), which are useful for SPAD device testing and selection, have fairly limited application. Suitably designed active-quenching circuits (AQC's) make it possible to exploit the best performance of SPAD's. Thick silicon SPAD's that operate at high voltages (250-450 V) have photon detection efficiency higher than 50% from 540- to 850-nm wavelength and still ~3% at 1064 nm. Thin silicon SPAD's that operate at low voltages (10-50 V) have 45% efficiency at 500 nm, declining to 10% at 830 nm and to as little as 0.1% at 1064 nm. The time resolution achieved in photon timing is 20 ps FWHM with thin SPAD's; it ranges from 350 to 150 ps FWHM with thick SPAD's. The achieved minimum counting dead time and maximum counting rate are 40 ns and 10 Mcps with thick silicon SPAD's, 10 ns and 40 Mcps with thin SPAD's. Germanium and III-V compound semiconductor SPAD's extend the range of photon-counting techniques in the near-infrared region to at least 1600-nm wavelength.

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Scaling analysis of phase-change memory technology

Pirovano

et al.

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Novel /spl mu/trench phase-change memory cell for embedded and stand-alone non-volatile memory applications

et al. 2004

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Single-photon detection beyond 1 μm: performance of commercially available InGaAs/InP detectors

et al. 1996

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Commercially available InGaAs/lnP avalanche photodiodes, designed for optical receivers and range finders, can be operated biased above the breakdown voltage, achieving single-photon sensitivity. We describe in detail how to select the device for photon-counting applications among commercial samples. Because of the high dark-counting rate the detector must be cooled to below 100 K and operated in a gated mode. We achieved a noise equivalent power of 3 × 10(-16) W/Hz(1/2) to a 1.55-µm wavelength and a time resolution well below 1 ns with a best value of 200-ps FWHM. Finally we compare these figures with the performance of state-of-the-art detectors in the near IR, and we highlight the potentials of properly designed InGaAs/lnP avalanche photodiodes in single-photon detection.

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Double epitaxy improves single-photon avalanche diode performance

Lacaita

Ghioni

Cova

1989

Electron. Lett. (UK)

131

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A.L. Lacaita

Avalanche photodiodes and quenching circuits for single-photon detection

Scaling analysis of phase-change memory technology

Novel /spl mu/trench phase-change memory cell for embedded and stand-alone non-volatile memory applications

Single-photon detection beyond 1 μm: performance of commercially available InGaAs/InP detectors

Double epitaxy improves single-photon avalanche diode performance

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