Dimension of Hilbert Space in Quantum Mechanics

In summary: Capri mentioned earlier).In summary, the space can be spanned by the |x> basis which is a non-countable set of infinite basis kets. But then isn't this a contradiction, since the cardinality of any set of basis vectors spanning the same space must be the same. In other words there must exist a bijective mapping from the one set of basis vectors to another set of basis vectors, whereas in this case we cannot define such a mapping from a countably infinite set to a non-countable infinite set.
  • #1
vinay uppal
8
0
We know that the Hilbert space of wavefunctions can be spanned by the |x> basis which is a non-countable set of infinite basis kets. Now consider the case of a particle in a box. We say that the space can be spanned by the energy eigenkets of the hamiltonian (each eigenket corresponds to an energy eigenvalue). Since the energy eigenvalues are discrete, therefore the set of corresponding eigenkets must form a countable set of infinite kets. But then isn't this a contradiction, since the cardinality of any set of basis vectors spanning the same space must be the same. In other words there must exist a bijective mapping from the one set of basis vectors to another set of basis vectors, whereas in this case we cannot define such a mapping from a countably infinite set to a non-countable infinite set.
 
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  • #2
vinay uppal said:
We know that the Hilbert space of wavefunctions can be spanned by the |x> basis which is a non-countable set of infinite basis kets.

This is not a basis for the Hilbert space, since the |x> do not actually live in the Hilbert space. See rigged Hilbert spaces or Gelfand triples.
 
  • #3
For another paradox related to this, see

https://www.physicsforums.com/showthread.php?t=122063&highlight=dirac.

Standard quantum mechanic books that have short treatments of rigged Hilbert spaces/Gelfand triples include Nonrelativistic Quantum Mechanics by Anton Z. Capri, Quantum Mechanics: A Modern Development by Leslie Ballentine, and Quantum Mechanics: Foundations and Applications by Arno Bohm. See also the Chapter 14, Bras, kets, and all that sort of thing, in Mathematics for Physics and Physicists by Walter Appel.

A couple of heuristic not so careful posts by me explaining this sort of thing are

http://groups.google.ca/group/sci.physics/msg/48b32de855207a90?dmode=source

http://groups.google.ca/group/sci.physics/msg/4e62f4fa46ef8b73?dmode=source.

As far as I know, almost all (actual) Hilbert spaces used in quantum mechanics are separable, i.e., they have countable orthonormal bases (not to be confused with Hamel bases).
 
  • #4
That was an awesome paradox! Too good! And enlightening!

Anyway, returning to my question,I understood your point that |x> does not live in the Hilbert space.Thanks!

Let us not call the space of wavefunctions for a particle in a box as Hilbert space. Let us call it some space (say space X). This space can be spanned by |x> basis and the countably infinite energy basis kets (as in, you can express any wavefunction in |x> basis as well as the energy basis). How is this possible?
 
  • #5
what are infinite basis kets |x>? why do they span the same subspace of the [itex]L^2[/itex] space as the eigenkets of the hamiltonian?
 
  • #6
vinay uppal said:
Let us not call the space of wavefunctions for a particle in a box as Hilbert space. Let us call it some space (say space X). This space can be spanned by |x> basis and the countably infinite energy basis kets (as in, you can express any wavefunction in |x> basis as well as the energy basis). How is this possible?

Think of wavefunction space as lying inside the larger space as a proper subset. Anything inside the larger space, including stuff in proper subsets, can be expanded in terms of the generalized eigenstates |x>. Find an orthonormal basis (e.g., energy eigenstates) for the proper subset, in terms of which anything inside the proper subset can be expanded. Stuff outside the proper subset, however, cannot be expanded in terms of a basis of the proper subset.
 
  • #7
Hmmm, why not use wave packets? The position representation is unphysical anyway. So, instead of attempting to definine a state corresponding to a particle being located at exactly a certain position using a mathematical tour de force, you can just as well work with Gaussian wave packets. You can cut them off to be exactly zero outside some range using infinitely differentiable functions if you like.

The Fourier transform of Gaussians are Gaussians, so you get wave packets for the momentum eigenstates in the same form.
 
  • #8
Count Iblis said:
Hmmm, why not use wave packets? The position representation is unphysical anyway. So, instead of attempting to definine a state corresponding to a particle being located at exactly a certain position using a mathematical tour de force, you can just as well work with Gaussian wave packets. You can cut them off to be exactly zero outside some range using infinitely differentiable functions if you like.

The Fourier transform of Gaussians are Gaussians, so you get wave packets for the momentum eigenstates in the same form.

Yes, I commented on this in the third reference that I gave in post #3,
George Jones said:
Nevertheless, quantum mechanics has a (somewhat) nice Hilbert space formulation (due to Von Neumann) that neither needs nor uses delta functions or any other non-square-integrable beasts (e.g., plane waves).

Two points: many physicists do not want to give up the elegance (and occasional ugliness) of full Dirac notation; quantum mechanics in Hilbert space, done in a mathematically honest way, is itself quite daunting (see, e.g., the books by Reed and Simon).
 

1. What is a Hilbert space in quantum mechanics?

A Hilbert space is a mathematical concept used in quantum mechanics to describe the states of a quantum system. It is a complex vector space with an inner product defined on it, and it allows for the representation of quantum states as vectors. In other words, it is a mathematical framework that allows us to describe and manipulate quantum systems.

2. How is the dimension of a Hilbert space determined?

The dimension of a Hilbert space is determined by the number of basis vectors needed to span the space. In quantum mechanics, this corresponds to the number of orthogonal states that can be used to represent a quantum system. The dimension is typically denoted by the letter N and can range from a finite number to infinity depending on the system being studied.

3. Why is the dimension of a Hilbert space important in quantum mechanics?

The dimension of a Hilbert space is important because it determines the number of possible states that a quantum system can have. This, in turn, affects the complexity of the system and the types of calculations that can be performed. In addition, the dimension of a Hilbert space is related to the number of observables that can be measured in a system, providing important information about its physical properties.

4. Can the dimension of a Hilbert space change?

Yes, the dimension of a Hilbert space can change depending on the physical system being studied. For example, in quantum field theory, the dimension of a Hilbert space can change as the number of particles in a system changes. Additionally, the dimension of a Hilbert space can also change if the system undergoes a phase transition, resulting in a different set of basis vectors being needed to describe the system.

5. How does the dimension of a Hilbert space relate to the uncertainty principle?

The uncertainty principle in quantum mechanics states that certain pairs of physical properties, such as position and momentum, cannot be precisely measured at the same time. The dimension of a Hilbert space is directly related to this principle, as the number of states that can be described in a system is limited by the dimension of the Hilbert space. This means that there is a fundamental limit to the precision with which certain properties can be measured, as determined by the dimension of the Hilbert space.

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