Cyclotron radiation wavelengths can be tuned, as they aren’t tied to valence shells.
The number of spots per second from thermal statistics plus harmonics on the cyclotron radiation can be calculated. If the electrons are also absorbing photons classically, you should get extra spots when they happen to add up.
I think you’re going to see Rhydberg-OrphanWilde-interpretation blackbody radiation anyway. When an electron bounces off another, it counts as acceleration and produces cyclotron radiation. It might be different in magnitude, though.
I think photoplates can be tuned too. It should have to be hit by a single particle with more than the activation energy for the light-sensitive reaction. (Neglecting tunneling.) Therefore, it should be possible to pick a compound with a suitably high activation energy.
If you’re emitting enough radiation to create spots in the receiving medium, you’re dealing with energy that is at least occasionally above Planck scales, and this energy is already in the emitting medium.
But it will look statistically different. From what I understand, photons below the necessary energy will just bounce off or get absorbed by some other process. That’s how the photoelectric effect is supposed to work, anyway.
I’m not familiar enough with cyclotron radiation (read: I’m not familiar with it at all; my understanding of cyclotrons is limited to “They’re the things hospitals and labs use to produce small amounts of radioactive isotopes”) to be able to contribute to this discussion, so I’m afraid I’ll have to tap out due to ignorance I currently don’t have time to rectify.
Cyclotron radiation wavelengths can be tuned, as they aren’t tied to valence shells.
The number of spots per second from thermal statistics plus harmonics on the cyclotron radiation can be calculated. If the electrons are also absorbing photons classically, you should get extra spots when they happen to add up.
I think you’re going to see Rhydberg-OrphanWilde-interpretation blackbody radiation anyway. When an electron bounces off another, it counts as acceleration and produces cyclotron radiation. It might be different in magnitude, though.
I think photoplates can be tuned too. It should have to be hit by a single particle with more than the activation energy for the light-sensitive reaction. (Neglecting tunneling.) Therefore, it should be possible to pick a compound with a suitably high activation energy.
But it will look statistically different. From what I understand, photons below the necessary energy will just bounce off or get absorbed by some other process. That’s how the photoelectric effect is supposed to work, anyway.
I’m not familiar enough with cyclotron radiation (read: I’m not familiar with it at all; my understanding of cyclotrons is limited to “They’re the things hospitals and labs use to produce small amounts of radioactive isotopes”) to be able to contribute to this discussion, so I’m afraid I’ll have to tap out due to ignorance I currently don’t have time to rectify.