Does Conservation of Momentum Apply to Electron/Atom Interactions?

In summary, electrons have a theoretical rest mass and exhibit quantum characteristics in their behavior. When an electron collides with an atom, conservation of momentum applies in a classical sense. However, the energy exchange may be effected in a directly unmeasurable way, such as electron-electron momentum change. When firing electron plasma towards an atom, the atom will experience recoil and its movement in space may be perturbed. This holds true for any type of beam, including light. The quantum behavior becomes nontrivial when the electrons are bound in the process.
  • #1
cremor
19
3
Electrons have a theoretical rest mass. They can move at varying speeds through space, unlike photons. They ehxhibit quantum-characteristics in their behavior. If an electron collides with, say, an atom, does conservation of momentum apply in the classical sense or does measurable mass (an atom nucleus) evade this effect, and the energy exchange is effected only in the directly unmeasurable way, in this instance for example electron-electron momentum change (among other effects)?

In case I ask it too vaguely, if you fire electron plasma towards an atom in a void, does the atom get blasted out of the jet's way, or is its movement in space left unperturbed? Turn this around, should the electron emitter experience recoil thrust from firing the plasma?
 
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  • #2
Everything you say can be treated essentially classically, except that one may perhaps have to add small quantum corrections. The quantum behavior starts to begin nontrivially only when the electrons is or can be bound in the process.
 
  • #3
There's nothing special about electrons in this regard. Shoot a beam of anything, including light, and you will have recoil. Conservation of momentum is one of the most important and general laws.
 

Related to Does Conservation of Momentum Apply to Electron/Atom Interactions?

1. Does conservation of momentum apply to electron/atom interactions?

Yes, conservation of momentum applies to all interactions between particles, including electrons and atoms. This principle states that the total momentum of a closed system remains constant, meaning that the momentum of the particles before and after the interaction must be equal.

2. How does conservation of momentum apply to electron/atom interactions?

In the case of electron/atom interactions, the momentum of the electrons and atoms are affected by each other's presence and movement. However, the total momentum of the system (both the electrons and atoms) remains constant. This means that any changes in momentum of the electrons are balanced by changes in momentum of the atoms, ensuring that the total momentum is conserved.

3. Can conservation of momentum be violated in electron/atom interactions?

No, conservation of momentum is a fundamental law of physics and cannot be violated in any interaction between particles, including electron/atom interactions. Any change in momentum within the system must be balanced by changes in the opposite direction, ensuring that the total momentum remains constant.

4. What are some real-life examples of conservation of momentum in electron/atom interactions?

One example is the photoelectric effect, where photons (particles of light) interact with electrons in a material. The momentum of the photons is transferred to the electrons, causing them to be ejected from the material. Another example is in particle accelerators, where high-energy electrons collide with atoms, causing changes in momentum and the creation of new particles.

5. Are there any exceptions to conservation of momentum in electron/atom interactions?

No, conservation of momentum is a universal law and has been confirmed by countless experiments and observations. However, in certain cases, it may appear that momentum is not conserved. This is due to external forces or factors that are not accounted for in the system, such as friction or external magnetic fields. In these cases, the total momentum may appear to change, but it is actually being transferred to or from the system by these external forces.

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