Mentz114 said:
dmtr:
To calculate the wave function of a system I need to find the Hamiltonian of the system, then solve Schroedingers equation. Now I am in a position to work out the eigenvalues and the probabilities associated with them. This procedure gives results which agree with experiment. There is explicit entropy term in this calculation.
Are you suggesting one should include an environmental part in the Hamiltonian which will affect the final probabilities ? In the density matrix formalism it is possible to explain the 'selection' of the observed eigenstate by doing this - but it doesn't affect the probabilities calculated from the wave function.
AFAIK it doesn't affect the probabilities because of the infinities, right? If you use that approach, the single photon scattering in the environment over the infinite time would give the same infinite entropy release to the environment as two photons scattering, right? So you would have [tex]S_{A} = S_{B} \rightarrow \infty[/tex]. I think there is at least one boundary condition - we should only consider the entropy, produced by the apparatus in the space-time light cone of the observer. I don't know if it is infinite, or not.
I'm not sure what the answer is. I'm a CS graduate and I only had a few overview courses on quantum mechanics and quantum information theory. My guess is that just calculating the number of states from the entropy would give us approximate counter values:
[tex]N_{A}/N_{B} \approx e^{\frac{S_{A} - S_{B}}{k}}[/tex]
I also think that he extreme case of [tex]S_{C} \rightarrow 0[/tex], [tex]S_{P} \rightarrow 0[/tex], [tex]S_{H} \rightarrow \infty[/tex] shows us very clearly that the heater 'sucks' photons from the path B. So I wouldn't be surprised if the switching on a largish heater in the real life would diminish the [tex]N_{B}[/tex] increase rate.
It also makes sense, that by introducing the potential to release a lot of entropy you create a potential well. And the equilibrium moves towards it.
Here is a question for you: what if we will couple 'the computation is complete' state of a quantum computer with a large release of entropy to the environment? Would it speed up the computation?
-- Dmtr