Schrodinger Equation and wavefunction collapse

In summary, the Schrodinger Equation for the hydrogen atom gives discrete energy levels that agree with experiment, but the concept of wave function collapse is not needed. The collapse of the wavefunction is associated with measurement, where the atom is forced to collapse into one of the measured states. Before measurement, the atom is in a superposition of all possible states. The same concept applies to the famous Schrodinger's cat thought experiment. Decoherence is a useful tool for some applications, but it does not solve all the problems and there is no equivalence rule between interpretations. While some physicists still discuss QM, most adhere to the "shut up and calculate" approach.
  • #1
feynmann
156
1
If we solve the Schrodinger Equation for hydrogen atom, we get discrete energy levels that agree with experiment. But no where we need the wave function collapse. So my question is where the wave function come from and why do we need it?
 
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  • #2
The collapse of the wavefunction is associated with measurement. If you perform a measurement on the hydrogen atom, you force the wavefunction to collapse into one of the eigenvectors of the measured observables.

Before measurement, the atom is in a superposition of all possible states. You get a superposition of all the discrete energy levels. But it is only upon observation that you get a specific spectral line (or photon). And repeated measurements (or observing many atoms at once) gives the whole atomic spectrum as we know it.
 
  • #3
Jackson Tan said:
The collapse of the wavefunction is associated with measurement. If you perform a measurement on the hydrogen atom, you force the wavefunction to collapse into one of the eigenvectors of the measured observables.

Before measurement, the atom is in a superposition of all possible states. You get a superposition of all the discrete energy levels. But it is only upon observation that you get a specific spectral line (or photon). And repeated measurements (or observing many atoms at once) gives the whole atomic spectrum as we know it.

Do you really believe that before measurement, the atom is in a superposition of all possible states. How about cat, before measurement, is the cat in a superposition of life and death?
 
  • #4
feynmann said:
Do you really believe that before measurement, the atom is in a superposition of all possible states. How about cat, before measurement, is the cat in a superposition of life and death?

I leave it up to your philosophy to answer that :smile:! It is a postulate of QM that a measurement changes a superposition to a definite eigenstate. Prior to that, it is a superposition of states. What this means in reality, well, is beyond experiments.
 
  • #5
feynmann said:
Do you really believe that before measurement, the atom is in a superposition of all possible states. How about cat, before measurement, is the cat in a superposition of life and death?

What makes you think you can treat that which is measured and that which is measuring as separate systems?
 
  • #6
Jackson Tan said:
I leave it up to your philosophy to answer that :smile:! It is a postulate of QM that a measurement changes a superposition to a definite eigenstate. Prior to that, it is a superposition of states. What this means in reality, well, is beyond experiments.

Why is the Copenhagen interpretation being taken for granted here?
 
  • #7
See Quantum Decoherence.

See also Murray Gell-Mann's classical 'Quark and the Jaguar'

Schrodinger's cat 'problem' is not considered to be a problem at all.

The box is in contact with the environment, there's decoherence and the cat dies or lives.
 
  • #8
sokrates said:
See Quantum Decoherence.

See also Murray Gell-Mann's classical 'Quark and the Jaguar'

Schrodinger's cat 'problem' is not considered to be a problem at all.

The box is in contact with the environment, there's decoherence and the cat dies or lives.

If Schroedinger's cat is a problem in some interpretation, decoherence cannot solve it. With decoherence, a macroscopic superposition becomes even more macroscopic, without remaining to be a superposition.

Decoherence may be a useful tool for some applications, not more.
 
  • #9
I don't think there is any 'equivalence rule' between the interpretations that states 'if there's a problem in some interpretation, it exists in all interpretations'.

This is just not true. There are certain, tangible problems in the Copenhagen interpretation and Schrödinger's Cat is one of them. And decoherence 'supposedly' (and succesfully) solves the so-called 'measurement problem'.

But it would be absolutely unfair to bring all the interpretations down to some base level and say they are equivalent.

If they are just saying the same thing, why on Earth physicists are still discussing QM even after 80 years later?
 
  • #10
sokrates said:
why on Earth physicists are still discussing QM even after 80 years later?

They don't, nowadays it is mostly a topic that comesup on Internet forums :wink:
Most working physicists simply do not care that much about different interpretations of QM, mianly because there is no way to tell which one is correct.
There is a small number of people (some of them well known) that work on the "foundations" of QM but most people who use QM in their daily woprk (which means most physicists) adhere to the "shut up and calculate" school.
 
  • #11
Good point :)

you convinced me.

But the proportion may not be that small, after all how many physicists work on, say, electronic transport properties of proteins??

The venerable Murray Gell-Mann is working on this field! That's enough! :)
 

1. What is the Schrodinger Equation?

The Schrodinger Equation is a mathematical equation that describes the evolution of a quantum mechanical system over time. It is a fundamental equation in quantum mechanics and is used to calculate the probability of finding a particle in a certain state.

2. What is the significance of wavefunction collapse?

Wavefunction collapse is a concept in quantum mechanics that occurs when a particle is observed or measured. It is the sudden and unpredictable change of the wavefunction, which describes the probability of finding the particle in a particular state. This collapse is significant because it demonstrates the probabilistic nature of quantum mechanics and the role of observation in determining the state of a particle.

3. How is the Schrodinger Equation related to wavefunction collapse?

The Schrodinger Equation is used to calculate the wavefunction of a quantum system. When an observation is made, the wavefunction collapses, and the Schrodinger Equation is used to calculate the new wavefunction for the observed state. This process is known as the collapse postulate in quantum mechanics.

4. Can the Schrodinger Equation and wavefunction collapse be visualized?

The Schrodinger Equation and wavefunction collapse cannot be visualized in the traditional sense, as they describe the behavior of particles at the quantum level. However, there are mathematical and conceptual models that can help in understanding these concepts.

5. Are there any practical applications of the Schrodinger Equation and wavefunction collapse?

Yes, the Schrodinger Equation and wavefunction collapse have many practical applications in quantum mechanics, such as predicting the behavior of atoms and molecules, developing quantum computing algorithms, and understanding the behavior of particles in quantum systems. They are also essential in various technologies, including lasers, transistors, and medical imaging devices.

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