If a system is made of 3 atoms with no degeneracy with energy levels

In summary: So there are in fact an infinite number of states, and not just 3 as the destructor seems to be implying.In summary, the system has three microstates.
  • #1
iontail
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if a system is made of 3 atoms with no degeneracy with energy levels of fro example 0, e, 2e

would it be safe to say that the system only has three microstate or will it be 2^3 microstates.

if it is 2^3 can you please explain why?
 
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  • #2


It's 3 microstates. and won't be 8 anyway, it may be 6 "configurations" not microstates as follows:

classical mechanics says that it's 6=3x2x1 different configurations, because the particles would be distinguishable, like if you have 3 numbered balls in 3 different boxes, and you want to count how many configurations are possible.

Quantum mechanics says that particles like electrons are not distinguishable, therefore you have less configurations by N!, and so you only have 1 possible configuration, and yet three microstates. This gives the rise to Gibbs paradox, you can find something about that in Wikipedia.

I hope I answered your question.

good luck :)
 
  • #3


thankyou veryy much
 
  • #4


Welcome :)
 
  • #5


iontail said:
if a system is made of 3 atoms with no degeneracy with energy levels of fro example 0, e, 2e

would it be safe to say that the system only has three microstate or will it be 2^3 microstates.

if it is 2^3 can you please explain why?


Each atom can be in three states. To specify the state of the three atom system means telling in which of the three state each individual atom is, so there are 3^3 = 27 microstates for the three atom system.

TheDestroyer's explanation is wrong and on the indistinguishability issue he is misleading, because if we talk about atoms that can be in certain energy level, we are usually talking about a system in which the atoms are in some position and the energy level refers to the electronic states only.

If you have a system in which you have three atoms in a box and the state refers to the complete quantum state that includes the translational motion, then depending on whether the atoms are Bosons or Fermions, can they be in the same state or not. Also, permuting te atoms does not yield a new state. But for system in which you have 3 atoms in 3 posible states, you can't divide by factorial 3 to take that into account, as you can easily see by writing down all the states.
 

1. What is degeneracy in a system?

Degeneracy in a system refers to the number of ways that a given energy level can be occupied by particles. In other words, it is the number of distinct quantum states that have the same energy.

2. Can a system with 3 atoms have degeneracy in its energy levels?

No, a system with 3 atoms cannot have degeneracy in its energy levels because there are only 3 atoms present and therefore, only 3 distinct energy levels. Degeneracy occurs when there are more particles than energy levels, resulting in multiple particles occupying the same energy level.

3. How does the number of atoms in a system affect its degeneracy?

The number of atoms in a system directly affects the degeneracy of its energy levels. If there are more particles than energy levels, there will be degeneracy. If there are fewer particles than energy levels, there will be no degeneracy.

4. What is the significance of degeneracy in a system?

Degeneracy has important implications in quantum mechanics, specifically in the behavior of particles at the subatomic level. It can affect the properties of a system, such as its heat capacity, and also plays a role in determining the stability of a system.

5. How is degeneracy calculated in a system?

Degeneracy can be calculated by using the formula degeneracy = number of particles - number of energy levels. If the result is greater than 1, there is degeneracy in the system. If the result is less than or equal to 1, there is no degeneracy.

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