What happens when an electron is hit by a laser beam?

AI Thread Summary
When an electron in a vacuum encounters a laser beam, it can scatter light, transferring momentum and conserving the total momentum of the electron-photon system. The interaction can cause the electron to change direction, but not towards the laser; it can only be guided in specific directions. This phenomenon is utilized in particle accelerators, where lasers can accelerate particles without relying solely on electric fields. The scattering of the electron occurs at various angles, but the laser can effectively guide the electron's trajectory. Overall, lasers can influence electron motion, but with limitations on directionality.
The_Thinker
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Just a quick question. We know that an accelerated electron shoots out light, and light that falls on an electron in an atom, excites it. But what happens to an electron in vaccum, when it encounters a laser beam?

If an electron beam from an electron microscope, were to to intercept a laser beam, what would happen?

Would the beam be shifted in angle? And why if they are can lasers be used to accelerate particles in a particle accelerator instead of using an electric field?
 
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An electron can scatter light. The scattered light can transfer some momentum the electron, such that total momentum of the electron-photon system is conserved.

Ha e you heard of a light sail? If not, then Google it.
 
Light sails use mirrors, I was aware of them before. But I am specifically asking what direction an electron would be scattered in, in the presence of a laser.

Can a laser be used to guide an electron for instance? Or does the scattering take place in all angles?
 
Yes you can guide an ekectron with a laser.

Edit, but not every direction. You can't draw the electron toward the laser.
 

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