Where does an electron's kinetic energy go?

In summary, when an electron moves through a wire between two terminals on a battery, some of its potential energy is converted to kinetic energy. This kinetic energy may be converted to heat due to interactions with other electrons and the crystal structure. The kinetic energy of electrons in a circuit is negligible unless in a specialized application such as a particle accelerator. The energy delivered by the circuit is primarily from the movement of electrons from higher potential to lower potential. Analogously, it is like saying a grandfather clock is powered by the kinetic energy of the weights, when in reality it is the potential energy of the weights being converted to kinetic energy that powers the clock.
  • #1
LightningB0LT
6
0
When an electron moves through a wire between two terminals on a battery some of its potential energy is converted to kinetic energy. My question is, where does that kinetic energy go once it reaches the other terminal? Some of it is probably converted to heat, but what about the rest of it?
 
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  • #2
hw about in the chemical bond that it makes when its attached to an atom?
 
  • #3
Electrons are very light and move at a rather slow velocity. Their kinetic energy is completely negligible unless your application is a particle accelerator.
 
  • #4
mrspeedybob said:
Electrons are very light and move at a rather slow velocity. Their kinetic energy is completely negligible unless your application is a particle accelerator.

Absolutely incorrect. In a room temperature conductor electrons have random velocities which are a significant fraction of c. What is low is the DRIFT velocity imposed but the EMF of a circuit.

Some Kinetic energy is converted to heat due to interactions with other electrons and the crystal structure.
 
  • #5
Yes. I was referring to drift velocity. Thank you for the correction.

I am dubious however about the contribution of kinetic energy to the energy delivered by the circuit, including the energy converted to heat. The energy delivered by the circuit is the energy of electrons moving from higher potential to lower potential.

Talking about the kinetic energy of electrons in a circuit seems to me like talking about the kinetic energy of the weights that power a grandfather clock. Yes, they do move but it's a stretch to say the clock is powered by their kinetic energy.
 

1. Where does an electron's kinetic energy go?

Electrons are subatomic particles that have both mass and energy. When an electron is in motion, it has kinetic energy. This energy can be transferred or converted to other forms, depending on the environment and interactions with other particles.

2. Does an electron's kinetic energy disappear?

No, an electron's kinetic energy does not simply disappear. According to the law of conservation of energy, energy cannot be created or destroyed, only transferred or converted. So, the kinetic energy of an electron will always go somewhere else.

3. Can an electron's kinetic energy be converted to other forms?

Yes, an electron's kinetic energy can be converted to other forms of energy. For example, when an electron is accelerated through an electric field, its kinetic energy is converted to potential energy. Additionally, when an electron collides with another particle, its kinetic energy can be transferred to the other particle.

4. What factors influence where an electron's kinetic energy goes?

The environment and interactions with other particles play a significant role in determining where an electron's kinetic energy goes. For example, the presence of an electric or magnetic field can influence the direction and speed of the electron, thereby affecting where its kinetic energy will be transferred or converted.

5. Is an electron's kinetic energy ever completely lost?

In most cases, an electron's kinetic energy is not completely lost. However, in certain situations such as extreme temperatures or collisions with heavier particles, some of the kinetic energy may be dissipated as heat or sound energy. But even in these cases, the overall principle of energy conservation still applies.

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