A question about wave function

In summary: The normalization condition is a mathematical requirement to ensure that the probability of finding the particle somewhere in space is 1. Therefore, the wave function must go to zero at infinity in order to satisfy this condition. In summary, the wave function must go to zero at infinity in order to ensure that it is normalizable and to satisfy the probability interpretation of the wave function. This is a physically reasonable assumption, as we do not tend to encounter quantum delocalization over very large distances. For a free particle, the wave function is not normalizable and the particle is equally probable at all points, which is why the wave function does not go to zero at infinity.
  • #1
coki2000
91
0
Hello physicists,

My question is why a wave function has to be 0 at infinitiy. The author who I was studying him quantum book explains my question by saying that it is necessary to make wave function normalizable. But in my opinion there can be an arbitrary particle which can be found all around the universe therefore at infinity. Please illuminate me:smile: thank you all
 
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  • #2
There are two kinds of states for wave functions: bound states and scattering states. For bound states the energy of the particle is less than the potential energy at infinity, such a particle cannot be found at infinity and the wave function goes to zero at infinity. On the other hand for scattering states the energy of the particle is more than the potential energy at infinity. In this case the particle can be found anywhere and the wave function does not go to zero at infinity. The wave function for a free particle is such an example. The wave function in this case is not normalizable.
 
  • #3
Thank you Avijeet,
But for a particle, the probability to stand anywhere in space must be 1, mustn't it?
 
  • #4
You should think of it as a physically reasonable assumption you choose to make. If the wavefunction were not zero at infinity, wouldn't you find that surprising? :) We don't tend to encounter quantum delocalization over very large distances. Hence, this assumption.

Also: consider the normalized wavefunction (or its modulus-squared, the probability density). There is only so much probability to go around: it all has to add to 1. If your probability does not go to zero at infinity, the particle will be so "spread out" that you will never detect it in your laboratory -- so why are you analyzing that particle, instead of one that's a little closer to home?
 
  • #5
coki2000 said:
Thank you Avijeet,
But for a particle, the probability to stand anywhere in space must be 1, mustn't it?

For a free particle, the amplitude of the wave function at any point is a constant. The wave function is not normalizable, so the probability interpretation of the wave function is not applicable. All you can say is that the particle is equally probable at all the points.
 

1. What is a wave function?

A wave function is a mathematical description of the quantum state of a particle or system. It represents the probability of finding a particle in a specific position or state.

2. How does the wave function relate to quantum mechanics?

The wave function is a central concept in quantum mechanics, as it is used to describe the behavior of particles at the subatomic level. It allows us to understand and predict the behavior of particles in terms of probabilities rather than definite outcomes.

3. What is the Schrödinger equation and how does it relate to the wave function?

The Schrödinger equation is a fundamental equation in quantum mechanics that describes how the wave function of a quantum system evolves over time. It relates the energy of a particle to its wave function and allows us to make predictions about the behavior of particles.

4. Can the wave function be observed or measured?

No, the wave function itself cannot be observed or measured. It is a mathematical representation of the quantum state of a particle, and it is only through repeated measurements that we can determine the probability of finding a particle in a particular state.

5. How does the wave function collapse?

The wave function collapses when a measurement is made on a particle, causing it to be observed in a particular state. This is known as the collapse of the wave function, and it is a fundamental principle in quantum mechanics.

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