# How to count photons

How are photons counted?

What is the experimental setup used to count photons from a laser or even a lamp? Of course, in the case of the lamp, I would be able to count only the photons that pass through an area sensor in a particular observation point.

If at all possible, a setup that can be done at home is preferred--one that avoids expensive instruments as much as possible (I may be crazy to even think this is possible). The key point is:

We can't count photons like we count sheep. So how do we infer from the effects of single photons and count from there?

I can start with $E = \frac{hc}{\lambda}$, and all other manifestations of energy, like heat or motion.

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Dear Kit, you might have a look at en.wikipedia.org/wiki/Photomultiplier , rp-photonics.com/photon_counting.html and the references on these sites. Greets –  Robert Filter Feb 8 '11 at 9:39
A laser emits too many photons to count them individually, but you can measure the output power and divide it by the energy of a single photon. –  gigacyan Feb 8 '11 at 9:58

A single photon can easily be detected by a photomultiplier. The basic idea is that a photon hitting a metal plate in the tube ejects an electron from the metal plate by the photoelectric effect. An electric field inside the photomultiplier then accelerates the electron until it slams into another metal plate, releasing a bunch of electrons. These are then accelerated to a third metal plate, etc. The end result is a sizable current we can measure. The Wikipedia article is quite good and has more detail. You might be able to build a crude one at home with a lot of dedication, but it's a delicate device requiring a vacuum and quality electronics. These devices work for IR to UV light.

We can also measure individual photons with a scintillation counter. I used these in a couple of undergraduate labs to detect x-ray radiation from nuclear processes. They work by detecting when a photon (usually high-energy) ionizes an atom in some particular substrate, so they're tuned to detect photons at certain ranges of frequencies. The scintillator does not directly detect these photons, but converts them to several lower-energy photons that we can detect with other means to infer the high-energy photons' presence, so you'll need some more electronics to go with it. Still, we were able to watch single-photon events get counted in lab. (Thanks dmckee for clarification in comments).

The "rod" photoreceptors in your eye may be able to detect single photons. So you can detect single photons at home without any equipment, under the right circumstances.

One device you can fairly easily build at home is a cloud chamber, but it will detect mostly $\alpha$ and $\beta$ radiation rather than photons. However, you might see trails from high-energy photons (gamma radiation). There should be lots of sets of instructions on the web for how to build one.

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Nice, but I'm going to quibble about the scintillator: that's a mechanism to generate a bunch of lower energy (usually visible band) photons from one high energy one. Then you go about counting the visible photons with a PMT, MCP, or high QE photodiode. It might be better to talk about ionization detectors (Geiger tubes, proportional tubes and more sophisticated wire chambers) in that context. –  dmckee Feb 8 '11 at 20:40
@dmckee Yes, good point, thank you. –  Mark Eichenlaub Feb 8 '11 at 20:44
The eye photoreceptors will react to a single photon (ie the rhodopsin in the rods), but the brain will not register it. It needs around 5 or so to register in consciousness. –  Gordon Feb 8 '11 at 22:04
@dmckee: So the scintillator is some sort of down-converter? –  Kit Feb 9 '11 at 1:04
@Kit: Scintillators convert some of the energy lost by ionizing particles passing through them into light. High energy photons scatter electrons along their path, and it's their energy that the scintillator responds to. –  dmckee Feb 9 '11 at 2:31