Are stationery states eigenstates?

In summary: Therefore, it can be said that a system in an eigenstate of the Hamiltonian has a definite total energy. However, after a position measurement, this may no longer be the case. In summary, a quantum system in an eigenstate of the Hamiltonian has a definite total energy, but a position measurement may cause the system to no longer have a definite total energy.
  • #1
loom91
404
0
Hi,

I have a couple of newbie questions. Are all stationery solutions to a SE eigenstates of observables? Is the converse true (that is, are all eigenstates stationery)? If the answer is no, can a measurement collapse a stationery wave-function onto a non-stationery one? And finally, is the probability of a superposition collapsing into a component state given by the squared modulus of the co-efficient of the respective state? Thanks.

Molu, a clueless high-school boy who thinks QM is weird
 
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  • #2
There are many observables. The relevant one here is the Hamiltonian of the system, and its eigenstates are precisely the stationary states. This is clear from the Schrodinger equation;

[tex]\hat{H}\psi = i\hbar \frac{\partial \psi}{\partial t}[/tex]

In eigenstates of the Hamiltonain, the left side is a real multiple of the wavefunction [tex]\hat{H}\psi=E\psi[/tex] (E being the [real] eigenvalue). The solution of this ODE is of course [itex]\psi(t)=e^{-\frac{i}{\hbar}E t}\psi(0)[/itex], a stationary solution. The converse is also true.

A measurement collapses a wavefunction into an eigenstate of the observable corresponding to the measurement (i.e., position measurement~X operator, momentum measurement~P operator, etc.). If that observable is the Hamiltonian, of course this eigenstate is a stationary state. For other observables, this is not generally true. However, it is true when your observable A commutes with the Hamiltonian observable - i.e. [tex]\hat{A}\hat{H}=\hat{H}\hat{A}[/tex].

"And finally, is the probability of a superposition collapsing into a component state given by the squared modulus of the co-efficient of the respective state?"

Yes, that coefficent being in the expansion of the state in the eigenstate basis of the observable. The expansion must be a basis, and it must contain only eigenstates of your observable.
 
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  • #3
Thanks a lot, that's very helpful.

So if a state has a definite total energy, measuring its position may cause it to no longer have a definite total energy?
 
  • #4
Yes....
 
  • #5
what crap is this?

How can a state change its energy when measured?
One knows what energy a state has only be measuring it. This very process of measurement, collapses the wavefunction to the eigenstate, whose corresponding eigenvalue ( here energy ), our measurement yeilded.

Remember, that in a "no-hidden-variable theory", like our present QM, there is no pre-existing value, the measurement process itself ascribes a value to the system.
 
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  • #6
loom91 said:
Thanks a lot, that's very helpful.

So if a state has a definite total energy, measuring its position may cause it to no longer have a definite total energy?

If you make a measurement you simply change the state of the system. If it was in a state described as a linear combination of eigenstates then it shifts to one of the possible eigenstates. Measurement does not affect any eigenstate's energy. It simply causes a wavefunction to 'collapse'. So if your system was described by a linear combination of eigenstates, i.e.

[tex]\Psi(x,t) = \sum_{n=1}^{\infty}c_{n}\psi_{n}(x)exp(-i\frac{E_{n}t}{\hbar})[/tex]

(where some of the [itex]c_{n}[/itex]'s could be zero beyond some maximum value of N)

then upon a measurement the wavefunction collapses and is not described by the wave equation. The wavefunction evolves according to the Schrodinger equation under no measurement condition and when a measurement is taken, it collapses. These are two different processes.

[itex]\Psi_{n}(x,t)[/itex] is the wavefunction corresponding to the n-th eigenstate. So,

[tex]\Psi_{n}(x,t) = \psi_{n}(x)exp(-i\frac{E_{n}t}{\hbar})[/tex]

After measurement which eigenstate is occupied by the system cannot of course be determined. (Separation of variables gives rise to an exponential time varying factor that is a function of the energy of the n-th eigenstate multiplied by the spatial part of course. I hope you understand my notation)
 
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  • #7
An eigenstate, |u> of an observable B is a state which satisfies the relation

B|u> = b|u>

where b is the eigenvalue. A stationary state is one whose probability density is time independant. These are not the same things. It is possible for a state to be an eigenstate of an operator and the state not be a stationary state. An example is when the Hamiltonian operator is time-dependant, i.e. H = H(t). The Eigenvalues are the different energies the particle may have. The eigenstates will be a function of time. E.g. a charged particle in a time-dependant electromagnetic field yields such energies and non-stationary energy egenstates. I.e.

H(t)|u,t> E(t)|u,t>

Pete
 
  • #8
vroom said:
what crap is this?

How can a state change its energy when measured?
One knows what energy a state has only be measuring it. This very process of measurement, collapses the wavefunction to the eigenstate, whose corresponding eigenvalue ( here energy ), our measurement yeilded.

Remember, that in a "no-hidden-variable theory", like our present QM, there is no pre-existing value, the measurement process itself ascribes a value to the system.

I assume that you're referring to the exchange

loom91 said:
So if a state has a definite total energy, measuring its position may cause it to no longer have a definite total energy?

Rach3 said:
Yes.

with which I have no problem.

If a quantum system is prepared in a state of definite energy, i.e., in an eigenstate of the Hamiltonian, then, in general, after a position measurement, the system will no longer be in an eigenstate of the Hamiltonian.

Now, more detail. Assume an ensemble of identical physical systems are all prepared in the same energy eigenstate, and that this eigenstate has corresponding eigenvalue E. Immediately after state preparation, an energy measurement is made on each of the systems. With probability 1, i.e., with complete certainty, it can be prdicted that the result of each measurement is E. This is what is meant by "definite total energy."

Suppose that instead of energy measurements, position measurements are made on each each system immediately after state preparation. Immediately following the position measurements, energy measurements are made on each system. Then, there will be a statistical spread in the results of the energy measurements. This is what is meant by "measuring its position may cause it to no longer have a definite total energy".

I assume that you refer to the fact that in general, quantum system scannot be said to possesses properties, as demonstrated, for example, by the Kochen-Specker theorem. However, exceptions in language are often allowed for eigenstates of observables. In his book Quantum Theory: Mathematical and Structural Foundations, Chris Isham writes "a situation in which it arguable is meaningful to say that a system 'possesses' this value for A."

His italics.

Regards,
George
 
  • #9
vroom said:
what crap is this?

How can a state change its energy when measured?
One knows what energy a state has only be measuring it. This very process of measurement, collapses the wavefunction to the eigenstate, whose corresponding eigenvalue ( here energy ), our measurement yeilded.

Remember, that in a "no-hidden-variable theory", like our present QM, there is no pre-existing value, the measurement process itself ascribes a value to the system.

I'm not sure what you mean, we are talking about changing position, not energy. In any case, what is meant by energy or position here is the expectation value. A simple calculation reveals that for a stationery state (perfectly separable solutions to the TDSE) the standard deviation of the Hamiltonian is 0, so all measurements of energy yield the expectation value. Distinguishing between the measured energy and the expectation value of the enrgy is simply a matter of terminology here.
 
  • #10
pmb_phy said:
An eigenstate, |u> of an observable B is a state which satisfies the relation

B|u> = b|u>

where b is the eigenvalue. A stationary state is one whose probability density is time independant. These are not the same things. It is possible for a state to be an eigenstate of an operator and the state not be a stationary state. An example is when the Hamiltonian operator is time-dependant, i.e. H = H(t). The Eigenvalues are the different energies the particle may have. The eigenstates will be a function of time. E.g. a charged particle in a time-dependant electromagnetic field yields such energies and non-stationary energy egenstates. I.e.

H(t)|u,t> E(t)|u,t>

Pete

So separable solutions to the TDSE are energy eigenstates only when the Hamiltonian is time-independent? I never saw anyone mention this condition. Griffiths just says all stationery solutions are eigenstates of the Hamiltonian with the eigenvalue being the energy expectation value and the standard deviation 0. There's no mention of time-dependence of the Hamiltonian.
 
  • #11
And one more question, for any given hermetian operator A, do the eigenstates of A constitute an orthonormal basis spanning the complete Hilbert space?
 
  • #12
loom91 said:
So separable solutions to the TDSE are energy eigenstates only when the Hamiltonian is time-independent?
Yes.
I never saw anyone mention this condition. Griffiths just says all stationery solutions are eigenstates of the Hamiltonian with the eigenvalue being the energy expectation value and the standard deviation 0. There's no mention of time-dependence of the Hamiltonian.
He probably never got into situations with a time-dependant Hamiltonian. Look for such a Hamiltonian in his textbook as well as look for a place where he might have said that he will only address time-independant Hamiltonians. Note: If the Hamiltonian of a system is a function of time then the energy of the system is not conserved.

Pete
 
  • #13
loom91 said:
And one more question, for any given hermetian operator A, do the eigenstates of A constitute an orthonormal basis spanning the complete Hilbert space?

This is a deep and subtle question to which physicists and mathematicians might give different answers.

Do you mean hermitian or self-adjoint. If you mean self-adjoint, then a phyicist might answer "Yes, for each self-adjoint A there are eigenstates [itex]\left| a \right>[/itex] such that for every [itex]\left| \psi \right>[/itex] in Hilbert space,

[tex]\left| \psi \right> = \sum_{i} \left| a_{i} \right> \left< a_{i} | \psi \right> + \int \left| a_{\lambda} \right> \left< a_{\lambda} | \psi \right> d \lambda,[/tex]"

while a mathematician might answer "No, since, for example, the position operator has no eigenvalues or eigenvectors."

Other subtleties include: What does span mean in an infinite dimensional space? What is a Hilbert space? etc.

Regards,
George
 
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  • #14
Thats correct George, and the mathematicians will be completely correct. Hermiticity and self adjointness only coincide when the Hilbert space under consideration is finite dimensional (eg on a lattice or somesuch).

What physicists are really doing is working in a certain subspace of the full thing (often called the physical Hilbert space) where these things now are well defined.
 
  • #15
Haelfix said:
Hermiticity and self adjointness only coincide when the Hilbert space under consideration is finite dimensional (eg on a lattice or somesuch).

I don't think the question is one of dimension, I think it is one of boundedness. There exist Hermitian operators on infinite-dimensional Hilbert spaces, but these operators are necessarily (Hellinger-Toeplitz theorem) bounded. It is quite easy to show that for a quantum system, at least one of the conjugate position and momentum operators has to be unbounded, so Hermitian operators are not sufficient for observables in quantum theory. This introduces a lot a of grit (like operator domains that are not all of Hilbert space) into the mathematics that physicists can often ignore.

What physicists are really doing is working in a certain subspace of the full thing (often called the physical Hilbert space) where these things now are well defined.

I'd like to elaborate on this a bit.

Given a Hilbert space H (kets), there is a natural bijection between the space of continuous linear functionals H' (bras) on H. If we take the space of kets to be S, a proper subset of H, then the set S' of continuous linear functionals on S is "larger" than H'. This is because a mapping that is continuous on H is automatically continuous on S since S < H, but a mapping that is continuous on S does not have to continuous on elements of H that are outside of S.

So we have a (Gelfand) triple

S < H = H' < S'

Instead of taking ket space to be H and bra space to be H', take ket space to be S and bra space to be S', so there are "more" bras than kets. Another name for this setup is rigged Hilbert space.

Included in the bra space S' that is dual of of S, the space of physical states, are delta functions and plane waves, so this allows physicists to work with distributions as "bras", and these can be used as weak eigenvectors of, e.g., the position operator.

Regards,
George
 
  • #16
George Jones said:
So we have a (Gelfand) triple
[...]
Included in the bra space S' that is dual of of S, the space of physical states, are delta functions and plane waves, so this allows physicists to work with distributions as "bras", and these can be used as weak eigenvectors of, e.g., the position operator.
George, do you know of any good reference books (or articles or websites) on this topic that would be accessible at the early graduate level? I'm interested in learning about Gelfand triples in general from a mathematical point of view, and specifically how they allow us to use delta distributions and plane waves as eigenstates in physics.

Thanks,
Mike
 
  • #17
That went way over my head:( What I was asking was can all solutions to a Schroedinger equation be represented as linear combinations of the eigenstates of a particular observable? I'm only in high-school so please don't pull Gelfand triples and whatnots on me :D Thanks.
 
  • #18
loom91 said:
That went way over my head:( What I was asking was can all solutions to a Schroedinger equation be represented as linear combinations of the eigenstates of a particular observable? I'm only in high-school so please don't pull Gelfand triples and whatnots on me :D Thanks.
The answer to this question posted here is yes.

Pete
 
  • #19
loom91 said:
That went way over my head:( What I was asking was can all solutions to a Schroedinger equation be represented as linear combinations of the eigenstates of a particular observable? I'm only in high-school so please don't pull Gelfand triples and whatnots on me :D Thanks.

May I suggest Eisberg/Resnick and/or Griffiths...take the latter only if you have some background in differential and integral calculus, Fourier Series (and later Fourier Transforms) and complex variables. There are several other good books to chose (sadly some are out of print). Once you have the hang of the basic postulates then you could move on to the so called advanced texts.
 
  • #20
maverick280857 said:
May I suggest Eisberg/Resnick and/or Griffiths...take the latter only if you have some background in differential and integral calculus, Fourier Series (and later Fourier Transforms) and complex variables. There are several other good books to chose (sadly some are out of print). Once you have the hang of the basic postulates then you could move on to the so called advanced texts.

I don't know about Eisberg/Resnick, but I've been trying Griffiths as leisure reading, though I don't know anything about Fourier Analysis (they don't teach that in our school :).
 
  • #21
loom91 said:
That went way over my head:( What I was asking was can all solutions to a Schroedinger equation be represented as linear combinations of the eigenstates of a particular observable? I'm only in high-school so please don't pull Gelfand triples and whatnots on me :D Thanks.

I tried to give an answer in post #13, a part of which was meant to at about the level of Griffiths. Take a look also at what he says in the last paragraph on page 105 (second edition).

If you have questions about this, post, keep asking questions, and I'm sure someone will try to answer.

As I said, your question is very subtle. Thinking about it reminded me of the 1 = 0 paradox that I posted in a https://www.physicsforums.com/showthread.php?t=122063". This thread shows that sometime it's necessary to be a little bit careful.

My condolences about the the series of ODI's. o:)
 
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  • #22
mikeu said:
George, do you know of any good reference books (or articles or websites) on this topic that would be accessible at the early graduate level? I'm interested in learning about Gelfand triples in general from a mathematical point of view, and specifically how they allow us to use delta distributions and plane waves as eigenstates in physics.

Thanks,
Mike

As a start, you might want to look at chapters 6 and 8 from https://www.amazon.com/gp/sitbv3/reader/ref=sib_dp_pt/104-2608378-7414359?%5Fencoding=UTF8&asin=981024651X#reader-link"&tag=pfamazon01-20.

I'll try and make another post that has more references.
 
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  • #23
loom91 said:
I don't know about Eisberg/Resnick, but I've been trying Griffiths as leisure reading, though I don't know anything about Fourier Analysis (they don't teach that in our school :).

Griffiths first uses Fourier Transforms in the discussion of the Free particle wave function. But Fourier Series are used even in the infinite square well section. Your trajectory should be Fourier Series-->Fourier Integral-->Fourier Transform. OP might be able to suggest some good books/sites for this. Which section are you reading from Griffiths right now?
 
  • #24
maverick280857 said:
Griffiths first uses Fourier Transforms in the discussion of the Free particle wave function. But Fourier Series are used even in the infinite square well section. Your trajectory should be Fourier Series-->Fourier Integral-->Fourier Transform. OP might be able to suggest some good books/sites for this. Which section are you reading from Griffiths right now?

I happen to be the OP :) I'm currently reading the second chapter on TISE. I'm actually rereading this chapter because I want to have a better understanding of TISE as it's in our chemistry syllabus.
 
  • #25
George Jones said:
My condolences about the the series of ODI's. o:)

I (along with most in my state) was supporting West Indies.
 
  • #26
loom91 said:
I (along with most in my state) was supporting West Indies.

Cogratulations, then. It was nice to see Lara go out on top at home.

I'm currently reading the second chapter on TISE.

The material on eigenvalues and eigenvectors of Hermitian operators is in chapter 3. Griffiths might not be the easiest book for self-study, but I can't any other books that are better.
 
  • #27
Hi George

Where are you from? I am guessing you are not from the US because you were actually referring to the cricket matches! (I thought ODI is something in QM which I haven't studied so far :rofl:).

I am using Griffiths for self-study but in conjunction with other books like Eisberg/Resnick, Schiff, etc. I think if one knows enough calculus, Fourier Series and some Transforms Griffiths is pretty good :smile:

Cheers
Vivek

EDIT: Oh so you're from Canada...nice to see a cricket fan mate :-)
 

1. What are stationary states and eigenstates?

Stationary states and eigenstates are concepts in quantum mechanics that describe the energy states of a quantum system. Stationary states are energy states that do not change over time, while eigenstates are states in which a physical quantity (such as energy) has a definite value.

2. How do stationary states and eigenstates differ?

While stationary states are energy states that do not change over time, eigenstates are states in which a physical quantity has a definite value. In other words, all eigenstates are stationary states, but not all stationary states are eigenstates.

3. Why are stationary states important in quantum mechanics?

Stationary states are important in quantum mechanics because they provide a way to describe the energy levels of a quantum system. They also allow for the calculation of probabilities for different energy states, which is crucial for understanding the behavior of quantum systems.

4. How do we know if a state is a stationary state or an eigenstate?

The best way to determine if a state is a stationary state or an eigenstate is to calculate its energy using the Schrödinger equation. If the energy does not change over time, the state is a stationary state. If the state also satisfies the eigenvalue equation, it is an eigenstate.

5. Can a system be in both a stationary state and an eigenstate at the same time?

No, a system cannot be in both a stationary state and an eigenstate at the same time. This is because a stationary state is a state with a fixed energy, while an eigenstate has a definite value for a physical quantity. These two conditions cannot both be satisfied simultaneously.

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