SteamKing said:Is this a homework problem?
Menaus said:If the electrons have a high enough energy level, and they happen to hit an atom, is it possible that the electron would accelerate the atom to such a velocity that it would pass through the tube?
If an electron with 50 keV makes a 180°-turn at an atom (the maximal momentum exchange), a single proton just gets 27 eV of kinetic energy - but a single proton cannot do this. If you use a material with A=50, for example (like iron), this maximal energy drops to 1/2 eV. That is not enough to dislocate it in a solid material, so this process does not happen at all.If the electrons have a high enough energy level, and they happen to hit an atom, is it possible that the electron would accelerate the atom to such a velocity that it would pass through the tube?
mfb said:If an electron with 50 keV makes a 180°-turn at an atom (the maximal momentum exchange), a single proton just gets 27 eV of kinetic energy - but a single proton cannot do this. If you use a material with A=50, for example (like iron), this maximal energy drops to 1/2 eV. That is not enough to dislocate it in a solid material, so this process does not happen at all.
With higher electron energies - in the GeV range - this process is possible, but extremely rare. And then you still get an atom that moves a few atom diameters in the material, it won't fly around freely.
To get atoms to move through any macroscopic material, they need an energy of the order of MeV. You won't get this with an electron collision, independent of the energy - if the energy is really high (GeV++), you can split atoms, but that is a different process.Menaus said:In a Crookes tube an electron need not make a 180° turn. Also, somewhere I've heard of the use of single-electrode vacuum tubes for x-ray experiments, although I forgot where.
In any case, do you think it is plausible in this case?
sophiecentaur said:There is an arbitrary divide between X Rays and γ Rays and I have concluded that the best way to categorise the two (if you really insist that the name is that important) in terms of how they are generated. Earlier in this thread, there has been mention of X Rays of 'a mere 50kV' energy. Radiotherapy is carried out with X Rays with energy of 10MV. A linear accelerator is used to produce this energy and the photons are produced in exactly the same way as in more familiar, diagnostic X Ray machines. I don't think is is common, these days, to use radioactive sources for radiotherapy because you can't turn them OFF as easily.
The 10MV energy is certainly very "optimal" for deep radiation of tissue.
UltrafastPED said:This is inconsistent with the terminology that I learned in nuclear physics and plasma courses.
As for synchrotron radiation, let them speak for themselves:
http://www.esrf.eu/about/synchrotron-science/synchrotron-light
I agree that the division point is arbitrary, but I don't read papers where they call a 10 MeV photon "an x-ray". At higher energies they tend to simply mention the energy.
The X-ray tube optimum voltage is used to determine the maximum energy that can be produced by an X-ray tube. This voltage is essential for producing high-quality X-ray images as it controls the penetration of the X-rays through the patient's body.
The X-ray tube optimum voltage is determined by various factors such as the type of X-ray tube, the thickness and density of the patient's body part being imaged, and the desired image quality. The voltage is typically calibrated by a medical physicist to achieve the best balance between image quality and patient safety.
If the X-ray tube optimum voltage is too low, the X-rays produced will have low energy and may not penetrate through the patient's body. This will result in a poor quality image that may be difficult to interpret. Additionally, a low voltage can also lead to longer exposure times, increasing the risk of radiation exposure for the patient.
If the X-ray tube optimum voltage is too high, the X-rays produced will have high energy and may penetrate through the patient's body too easily. This can result in overexposure to radiation, which can be harmful to the patient. High voltage can also cause image artifacts, making the image difficult to interpret.
Yes, the X-ray tube optimum voltage can be adjusted for different imaging procedures. Different procedures may require different levels of energy to produce high-quality images. Therefore, the voltage can be adjusted accordingly by a medical physicist or a trained technologist to optimize the image quality while also ensuring patient safety.