Detecting Single Photon Energy

In summary, individual photons have discrete energies according to their wavelength, but for photons in the visible range, their energy is too small to be accurately measured. This is why we use filters before the CCD camera in a microscope to detect photons of different wavelengths. While there are detectors that can tell the energy of a single photon, they are not practical for detecting visible light. Some issues that may affect the accuracy of measuring single photon energy include thermal motions and dark count rates.
  • #1
splinewave
4
0
I was taught that individual photons have discrete energies (E = hv) according to their wavelength (which is a smooth parameter). Why then do we use filters before the ccd camera in a microscope to detect photons of different wavelengths?

Isn't there a detector that can tell me the energy (and therefore the wavelength) of a single photon?
 
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  • #2
splinewave said:
I was taught that individual photons have discrete energies (E = hv) according to their wavelength (which is a smooth parameter). Why then do we use filters before the ccd camera in a microscope to detect photons of different wavelengths?

Isn't there a detector that can tell me the energy (and therefore the wavelength) of a single photon?

For high energy photons, yes, detectors can tell the energy of a single photon. However, for photons in the visible range, their energy is so small, that we can barely detect them. In principle, one could, if the detection process is the photo-electric effect (ok), if the photo-electron would start out from a well-defined state of known energy (not ok in solid photocathodes, but in a gas, this can be ok), and if we could measure precisely the energy of the photo-electron (is not unthinkable).
But this is not the case for a photomultiplier.
As a CCD is an integrating device which accumulates the charge of many many photons in one pixel, and then measures the total charge, you see that this is even further away from measuring single-photon energies.

As I said, for X-ray photons, that's not a problem. Cooled germanium crystals can be used to measure the energy of such photons, and that's actually used a lot in spectroscopy. But for visible photons, the energy is too low to do that in practice.
 
  • #3
There's apparently more to consider. For example, a real detector will have thermal motions of its own, which will cause it to see phase jitter in an arriving pure tone, and hence a line spread. Several basic issues of this kind have been discussed some years ago at the SPIE Nature of Light: What is a Photon conference, as I recently found http://www.phys.uconn.edu/~chandra/" .
 
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  • #4
They won't tell you the energy of the incident photon, but avalanche photodiodes (APDs) are capable of detecting single photons with fairly high probability. Cooling an APD to cryogenic temperatures will lower the dark count rate.
 

1. What is the process of detecting single photon energy?

The process of detecting single photon energy involves using a highly sensitive detector, such as a photomultiplier tube or avalanche photodiode, to measure the energy of individual photons. This is typically done in a dark and controlled environment to minimize any interference from other sources of light.

2. How is the energy of a single photon measured?

The energy of a single photon is typically measured by converting the photon into an electrical signal using a detector. The amount of energy in the photon is then determined by the amplitude of the electrical signal, which is proportional to the energy of the photon. This measurement can be further refined by calibrating the detector with known sources of light.

3. What is the smallest amount of energy that can be detected by a single photon detector?

The smallest amount of energy that can be detected by a single photon detector is dependent on the specific type of detector being used. However, modern detectors are able to detect single photons with energies as low as a few femtojoules (10^-15 joules).

4. Can single photon detectors detect multiple photons at once?

No, single photon detectors are designed to only detect one photon at a time. This is because the detector must be able to differentiate between individual photons in order to accurately measure their energy. If multiple photons were to be detected at once, the energy measurement would be inaccurate.

5. What are some applications of single photon energy detection?

Single photon energy detection has a wide range of applications in various fields such as quantum optics, astronomy, and medical imaging. It is used in experiments to study the behavior of light at the quantum level, to detect faint signals in astronomical observations, and to improve the resolution and sensitivity of medical imaging techniques such as positron emission tomography (PET).

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