Can Liouville's theorem apply to dissipative systems

In summary, Liouville's theorem states that the phase space of a Hamiltonian system does not contract, meaning that systems with attractors or dissipative behavior cannot be represented by Hamiltonians. This behavior is typically attributed to ignoring degrees of freedom. For example, in a damped pendulum, the phase space volume contracts due to energy loss through air molecules. However, if all degrees of freedom are considered, the phase space volume is preserved.
  • #1
enricfemi
195
0
form the proof in Hamiltonian, i didn't find any clue.

the problem is i can't understand it even i know how to prove it.
 
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  • #2
Liouville's theorem applies to all mechanical systems if you don't ignore degrees of freedom.
 
  • #3
dx said:
Liouville's theorem applies to all mechanical systems if you don't ignore degrees of freedom.

Is this a correct expansion of what you are saying: Liouville's theorem says the phase space of a Hamiltonian system doesn't contract, so systems with attractors or dissipative systems can't be represented by Hamiltonians - but in principle the non-Hamiltonain behaviour comes from ignoring degrees of freedom?
 
  • #4
atyy said:
Is this a correct expansion of what you are saying: Liouville's theorem says the phase space of a Hamiltonian system doesn't contract, so systems with attractors or dissipative systems can't be represented by Hamiltonians - but in principle the non-Hamiltonain behaviour comes from ignoring degrees of freedom?

Yes, as far as we know, all mechanical systems are Hamiltonian. Non-Hamiltonian behavior (like friction, for example) is assumed to be due to ignoring degrees of freedom.
 
  • #5
Thanks for reply!
indeed, i raise the problem because of the attractors.
but can you say it more clearly?
how do we ignore degrees of freedom while dealing with non-Hamiltonian systems?
 
  • #6
Ok, let's suppose we have a damped pendulum. After a long time it will stop oscillating, no matter how hard you kicked it initially. So all trajectories in phase space end up at the same place, ie. the phase space volume has contracted.

But if we include all the air molecules which take energy away from the pendulum, then although the pendulum degrees of freedom eventually become identical for all trajectories, the air molecule degrees of freedom remain different, and those degrees of freedom preserve the phase space volume.
 
  • #7
that's amazing!:eek:
 

1. Can Liouville's theorem be applied to any type of dissipative system?

No, Liouville's theorem can only be applied to conservative systems, meaning those in which energy is conserved. Dissipative systems involve energy loss, and therefore, Liouville's theorem cannot be applied.

2. How does Liouville's theorem relate to dissipative systems?

Liouville's theorem is a fundamental law in physics that states the conservation of phase space volume in conservative systems. While it cannot be applied directly to dissipative systems, it can still be used in a modified form to study the behavior of these systems.

3. Can Liouville's theorem be used to predict the behavior of dissipative systems?

No, Liouville's theorem cannot be used to predict the behavior of dissipative systems. Dissipative systems involve energy loss, and therefore, their behavior cannot be predicted solely by the conservation of phase space volume.

4. Are there any limitations to applying Liouville's theorem to dissipative systems?

Yes, there are limitations to applying Liouville's theorem to dissipative systems. As mentioned before, Liouville's theorem can only be applied to conservative systems, so it cannot be used directly in dissipative systems. However, it can still provide insights and be used in modified forms to study dissipative systems.

5. Can Liouville's theorem be extended to include dissipative systems?

Yes, there have been efforts to extend Liouville's theorem to include dissipative systems. These extensions involve incorporating additional terms to the theorem to account for energy loss in dissipative systems. However, these extensions are still being researched and are not yet widely accepted in the scientific community.

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