Possibility of a smoothly wavelength-tunable x-ray/EUV source

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In summary, this device would be a major breakthrough for both research and practical usage. This is not my area of expertise; therefore I hope to get some help here.
  • #1
benjzhi
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Such a device would be a major breakthrough for both research and practical usage. This is not my area of expertise; therefore I hope to get some help here.

AFAIK there are four possible directions:

1. Gas discharge. It seems not to be tunable and could be applied for EUV only.
2. Beta rays collision with metals. It seems not to be tunable as well and could be applied for x-ray only
3. LC-circuit. Actually this is a science fiction. Unless doing it on nano level.
4. Free electron laser. I don't have any information about it.

Any comments, additions and corrections are more than welcome!

Thank you in advance!
 
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Now obviously you aren't going to be able to decrease the wavelength (higher energy) with something like this, but x-rays are on the right wavelength for atomic lattices in a crystal to act as a diffraction grating. In that case, might it be possible to tune the wavelength using a crystal as a diffraction grating in a manner similar to that done in spectrophotometers?
 
  • #3
uncanny_man said:
Now obviously you aren't going to be able to decrease the wavelength (higher energy) with something like this, but x-rays are on the right wavelength for atomic lattices in a crystal to act as a diffraction grating. In that case, might it be possible to tune the wavelength using a crystal as a diffraction grating in a manner similar to that done in spectrophotometers?
Interesting approach! I wonder whether any realization of your idea already exists...

So, basically, you are talking about using a classic x-ray source (or even EUV?) along with some cristal which is supposed to allow altering of the original wavelength. The only problem here is efficiency, because the result of such a diffraction will consist of rays of other wavelengths too.
 
  • #4
Absolutely. This is the approach often used in spectrophotometers: you break the light up into a rainbow and use a narrow slit to select a very specific wavelength range. That said, for a spectrophotometer you don't need to worry about the efficiency (obviously most of your light's energy is wasted). Are you in a situation where that matters?
 
  • #6
Oh yeah, you could only really separate out the light and select a wavelength if all of the wavelengths were present in the first place. Unfortunately, for a good intense beam of the full spectrum of x-rays, that pretty much leaves you using a synchrotron for your light source (from Brehmsstrahlung radiation).
 

1. What is a smoothly wavelength-tunable x-ray/EUV source?

A smoothly wavelength-tunable x-ray/EUV source is a device that is capable of producing x-rays or extreme ultraviolet (EUV) light with a range of wavelengths that can be precisely controlled and adjusted. This allows for more flexibility and accuracy in experiments and applications that require specific wavelengths of light.

2. How does a smoothly wavelength-tunable x-ray/EUV source work?

The source typically uses a high-intensity laser to ionize a gas, usually helium or neon, creating a plasma that emits x-rays or EUV light. By adjusting the intensity and duration of the laser, as well as the properties of the gas, the wavelength of the emitted light can be controlled.

3. What are the potential applications of a smoothly wavelength-tunable x-ray/EUV source?

This type of source has a wide range of potential applications, including material characterization, medical imaging, and advanced lithography for semiconductor manufacturing. It can also be used in research fields such as materials science, chemistry, and biology.

4. What are the advantages of using a smoothly wavelength-tunable x-ray/EUV source?

One major advantage is the ability to precisely control the wavelength of the emitted light, which is crucial for certain experiments and applications. Additionally, these sources are compact, relatively low-cost, and can produce high-intensity beams, making them well-suited for a variety of research and industrial settings.

5. Are there any challenges or limitations with this type of x-ray/EUV source?

One challenge is maintaining stability and consistency in the emitted wavelength, as any minor variations can greatly affect the results of experiments. Another limitation is the relatively narrow range of wavelengths that can be produced, making it less versatile compared to other types of x-ray/EUV sources. Additionally, the technology is still relatively new and ongoing research is needed to improve its capabilities and address any potential limitations.

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