quantum efficiency (original) (raw)

Definition: percentage of input photons which contribute to a desired effect

Alternative terms: quantum yield, photon detection efficiency

Categories: article belongs to category light detection and characterization light detection and characterization, article belongs to category physical foundations physical foundations

properties of photodetectors
- responsivity
- gain
- spectral response of a photodetector
- quantum efficiency
- photon detection efficiency
- dark current
- noise-equivalent power
- detectivity
- bandwidth
- dynamic range
- linearity
- (more topics)

Units: %

Formula symbol: ($\eta_\textrm{q}$)

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DOI: 10.61835/fxl Cite the article: BibTex BibLaTex plain text HTML Link to this page! LinkedIn

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What is a Quantum Efficiency?

The quantum efficiency (or quantum yield) is often of interest for processes which convert light in some way. It is defined as the percentage of the input photons which contribute to the desired effect. Examples are:

In a laser gain medium, the pump process may require the transfer of laser-active ions from one electronic level (into which the ions are pumped) to the upper level of the laser transition. This pump quantum efficiency is the fraction of the absorbed pump photons which contributes to the population in the upper laser level. This efficiency is close to unity (100%) for many laser gain media, but can be substantially smaller for others. It may depend on factors like the excitation density and parasitic absorption processes. It is not easy to measure, since the power conversion efficiency also depends on other factors, such as optical losses, which are not all easy to quantify.
Similarly, the quantum efficiency of fluorescence can be defined. It can be reduced by non-radiative processes such as multi-phonon transitions and energy transfer processes. If such effects do not occur, it can be essentially 100%.
In a photodiode (or some other photodetector, or a photovoltaic cell), the quantum efficiency can be defined as the fraction of incident (or alternatively, of absorbed) photons which contribute to the external photocurrent. (See the article on photocurrent for equations.) In the visible and near-infrared region, photodiodes can have quantum efficiencies above 90%, although values between 40% and 80% are more common. Photomultipliers can have much lower quantum efficiencies, strongly depending on the wavelength region.
For single-photon detectors, the term photon detection efficiency (PDE) is often used, which for most authors is not the same as quantum efficiency. Here, quantum efficiency is understood as the probability of obtaining a carrier from a photon, while PDE is the probability that an incident photon produces a registered detection event. This also requires that the generated carrier successfully initiates an avalanche. The probability for that can be significantly below unity, especially when the device is biased only slightly above breakdown.
PDE is defined under the assumption that the detector is ready to detect, i.e. not within its dead time following a previous avalanche. So although dead-time effects reduce the effective count rate in practice, they are not included in PDE.

Quantum Efficiencies Beyond 100%

2-micron emission with thulium with more than 100% quantum efficiency

Figure 1: 1.9-μm emission in a thulium-doped fiber laser with > 100% quantum efficiency.

In some special cases, the quantum efficiency of a laser or laser amplifier can be larger than unity. This is due to certain energy transfer processes between laser-active ions, which lead to a kind of cross-relaxation: starting with one ion in some excited state, a part of its energy is transferred to some other ion, which was originally in the electronic ground state, and both ions are finally in the upper laser level. This can, of course, only happen when the photon energy of the laser transition is lower than half that of the pump light, so that two generated photons together have less energy than one pump photon. An example, illustrated in Figure 1, is that of thulium-doped 1.9-μm fiber lasers, where ions are pumped into the level 3F2-4, and a cross-relaxation process (gray arrows) populates the upper laser level 3H4. This could in principle lead to a quantum efficiency of up to 200%. Values well above 100% can be reached in practice.

The quantum efficiency should not be confused with the quantum defect.

Suppliers

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SPAD 23 is a photon-counting array with 23 hexagonally packed single-photon avalanche diodes (SPADs) with best-in-class performance. The system software enables photon counting and time tagging and can be accessed through TCP/IP for easy integration into LabVIEW, MATLAB or Python. See our data sheet.

SPAD 512 is a camera integrating a 512×512 SPAD image sensor. Up to 100,000 fps in 1-bit mode enable high-speed imaging (photon-counting). Fine time gating enables the study of time-varying samples. See our data sheet.

SPAD Lambda is a linear detector with a 320×1 SPAD array. The detector is capable of both time gating and time stamping for the ultimate control over time-varying signals of interest. This arrangement is ideal for spectral detection applications. Thanks to microlenses and state-of-the-art production facilities, this detector offers high detection efficiency. See our data sheet.

⚙ hardware

The Hamamatsu Photonics MPPC (Multi-Pixel Photon Counter) is a device called SiPM, which is a photon counting device that is a multi-pixelized Geiger mode APD. While it is an optical semiconductor device, it has an excellent detection ability, so this device can be used in a variety of applications to detect very low-level light at the photon counting level.

Hamamatsu Photonics SPAD (Single Photon Avalanche Diode) is an element with a structure of a single pixel that combines a Geiger mode APD and a quenching resistor into one set. It is an optical semiconductor element that enables photon counting.

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