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Single Photon Detectors
By: Kobi Cohen Quantum Optics Seminar 25/11/09
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Outline A brief review of semiconductors Photodiode
P-type, N-type Excitations Photodiode Avalanche photodiode Geiger Mode Silicon Photomultipliers (SiPM) Photomultiplier Superconducting Wire Characterization of single photon sources HBT Experiment Second order correlation function
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Semiconductors Compounds
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Semiconductors electrons and “holes”: negative and positive charge carries Energy-momentum relation of free particles, with different effective mass
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Semiconductors Thermal excitations make the electrons “jump” to higher energy levels, according to Fermi-Dirac distribution:
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Semiconductors Excitations can also occur by the absorption of a photon, which makes semiconductors suitable for light detection: Energy conservation Momentum conservation photon momentum is negligible k2≈k1 useful to remember: (T=300K) Egap(eV) λgap(nm) Ge 0.66 1880 Si 1.11 1150 GaAs 1.42 870
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Intrinsic Semiconductors
Charge carriers concentration in a semiconductor without impurities:
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N-type Semiconductor Some impurity atoms (donors) with more valence electrons are introduced into the crystal:
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P-type Semiconductor Some impurity atoms (acceptors) with less valence electrons are introduced into the crystal:
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The P-N Junction Electrons and holes diffuse to area of lower concentration Electric field is built up in the depletion layer Drift of minority carriers Capacitance
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Biased P-N junction When connected to a voltage source, the i-V curve of a P-N junction is given by: We’ll focus on reverse biasing: larger electric field in the junction extended space charge region
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The P-N photodiode Electrons and holes generated in the depletion area due to photon absorption are drifted outwards by the electric field
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The P-N photodiode The i-V curve in the reverse-biased P-N junction is changed by the photocurrent Reverse biasing: Electric field in the junction increases quantum efficiency Larger depletion layer Better signal
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The P-I-N junction Larger depletion layer allows improved efficiency
Smaller junction capacitance means fast response
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Detectors: Quantum Efficiency
The probability that a single photon incident on the detector generates a signal Losses: reflection nature of absorption a fraction of the electron hole pairs recombine in the junction
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Detectors: Quantum Efficiency
Wavelength dependence of α:
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Summary: P-N photodiode
Simple and cheap solid state device No internal gain, linear response Noise (“dark” current) is at the level of several hundred electrons, and consequently the smallest detectable light needs to consist of even more photons
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Avalanche photodiode High reverse-bias voltage enhances the field in the depletion layer Electrons and holes excited by the photons are accelerated in the strong field generated by the reverse bias. Collisions causing impact-ionization of more electron-hole pairs, thus contributing to the gain of the junction.
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Avalanche photodiode P-N photodiode Avalanche photodiode
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Summary: APD High reverse-bias voltage, but below the breakdown voltage. High gain (~100), weak signal detection (~20 photons) Average photocurrent is proportional to the incident photon flux (linear mode)
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Geiger mode In the Geiger mode, the APD is biased above its breakdown voltage for operation in very high gain. Electrons and holes multiply by impact ionization faster than they can be collected, resulting in an exponential growth in the current Individual photon counting
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Geiger mode – quenching
Shutting off an avalanche current is called quenching Passive quenching (slower, ~10ns dead time) Active quenching (faster)
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Summary: Geiger mode High detection efficiency (80%).
Dark counts rate (at room temperature) below 1000/sec. Cooling reduces it exponentially. After-pulsing caused by carrier trapping and delayed release. Correction factor for intensity (due to dead time).
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Silicon Photomultipliers
SiPM is an array of microcell avalanche photodiodes (~20um) operating in Geiger mode, made on a silicon substrate, with pixels/mm2. Total area 1x1mm2. The independently operating pixels are connected to the same readout line
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SiPM: Examples
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Summary: SiPM Very high gain (~106)
Dark counts: 1MHz/mm2 (~20C) to 200Hz/mm2 (~100K) Correction factor (other than G-APD)
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Photomultiplier Photoelectric effect causes photoelectron emission (external photoelectric effect) For metals the work function W ~ 2eV, useful for detection in the visible and UV. For semiconductors can be ~ 1eV, useful for IR detection
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Photomultiplier Light excites the electrons in the photocathode so that photoelectrons are emitted into the vacuum Photoelectrons are accelerated due to between the dynodes, causing secondary emission
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Summary: Photomultiplier
First to be invented (1936) Single photon detection Sensitive to magnetic fields Expensive and complicated structure
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A remark – image intensifiers
A microchannel plate is an array consists of millions of capillaries (~10 um diameter) in a glass plate (~1mm thickness). Both faces of the plate are coated by thin metal, and act as electrodes. The inner side of each tube is coated with electron-emissive material.
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Superconducting nano-wire
Ultra thin, very narrow NbN strip, kept at 4.2K and current-biased close to the critical current. A photon-induced hotspot leads to the formation of a resistive barrier across the sensor, and results in a measurable voltage pulse. Healing time ~ 30ps
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SSPD – meander configuration
Meander structure increases the active area and thus the quantum efficiency
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End of 1st part !
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Hanbury Brown-Twiss Experiment (1)
Back in the 1950’s, two astronomers wanted to measure the diameters of stars…
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Hanbury Brown-Twiss Experiment (2)
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Hanbury Brown-Twiss Experiment (3)
In their original experiments, HBT set τ=0 and varied d. As d increased, the spatial coherence of the light on the two detectors decreased, and eventually vanished for large values of d.
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Coherence time The coherence time τc is originated from atomic processes Intensity fluctuations of a beam of light are related to its coherence
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Correlations (1) We shall assume from now on that we are testing the spatially-coherent light from a small area of the source. The second order correlation function of the light is defined by: (Why second order?)
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Correlations (2) For τ much greater than the coherence time:
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Correlations (3) On the other and, for τ much smaller than the coherence time, there will be correlations between the fluctuations at the two times. In particular, if τ=0 :
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Correlations: example
If the spectral line is Doppler broadened with a Gaussian lineshape, the second order correlation functions is given by:
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Summary: correlations in classical light
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HBT experiments with photons
The number of counts registered on a photon counting detector is proportional to the intensity
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Photon bunching and antibunching
Perfectly coherent light has Poissonian photon statistics Bunched light consists of photons clumped together
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Photon bunching and antibunching
In antibunched light, photons come out with regular gaps between them
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Experimental demonstration of photon antibunching
Antibunching effects are only observed if we look at light from a single atom
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Experimental demonstration of photon antibunching
Antibunching has been observed from many other types of light emitters
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Bibliography Fundamentals of Photonics, Saleh & Teich, Wiley 1991
Quantum Optics: An introduction, Mark Fox, Oxford University Press 2006 Hamamatsu MMPC datasheet (online) PerkinElmer APCM datasheet (online) Golts’man G., SSPD, APL 79(6),2001, Hanbury Brown, R. , and Twiss, R. Q. , Nature, 177, 27 (1956) Hanbury Brown, R. , and Twiss, R. Q. , Nature, 178, 1046 (1956)
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