Eigenfunction and Eigenvalue Confusion

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SUMMARY

The discussion focuses on identifying eigenfunctions of various quantum mechanical operators, including position, momentum, potential energy, kinetic energy, Hamiltonian, and total energy operators. The momentum operator is defined as \(\hat{p} = \frac{\hbar}{i}\frac{\partial}{\partial x}\), and it is established that \(\psi(x) = e^{ikx}\) is an eigenfunction with eigenvalue \(\hbar k\), while \(\psi(x) = \cos(kx)\) is not. The position operator \(\hat{x}\) and potential energy operator \([U]\) are clarified, with the conclusion that not all functions are eigenfunctions, particularly due to the nature of the operators involved.

PREREQUISITES
  • Understanding of quantum mechanics concepts, particularly operators and eigenfunctions.
  • Familiarity with the momentum operator \(\hat{p} = \frac{\hbar}{i}\frac{\partial}{\partial x}\).
  • Knowledge of complex functions and their role in quantum mechanics.
  • Basic grasp of potential energy and kinetic energy operators in quantum systems.
NEXT STEPS
  • Study the properties of eigenfunctions and eigenvalues in quantum mechanics.
  • Learn about the application of the position operator \(\hat{x}\) and its implications for wave functions.
  • Explore the role of complex numbers in quantum wave functions, particularly in relation to eigenfunctions.
  • Investigate the implications of potential energy operators in quantum systems and their eigenfunctions.
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Students and professionals in quantum mechanics, physicists analyzing wave functions, and anyone seeking to deepen their understanding of eigenfunctions and operators in quantum systems.

tarletontexan
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Homework Statement



given the following functions:
y(x)= Acos(kx)
y(x)=A sin(kx)-Acos(kx)
y(x)=Acos(kx)+iAsin(kx)
y(x)=A d(x-x0)

Which are eigenfunctions of the position, momentum, potential energy,kinetic energy, hamiltonian, and total energy operators

Homework Equations



y(x) is supposed to be \psi(x)

The Attempt at a Solution


I have a list of the operators in my book, but am unsure what the question is asking for...I know that operators are supposed to be multiplied to functions and the result is the functions times a constant. I am a little cloudy on the understanding and need a little bit of help clearing it up.
 
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You're just supposed to see if applying an operator to the function results in the original function times a constant. For example, take the momentum operator

\hat{p} = \frac{\hbar}{i}\frac{\partial}{\partial x}

The function \psi(x) = \cos kx isn't an eigenfunction because applying the operator yields

\hat{p}\psi(x) = \frac{\hbar}{i}\frac{\partial}{\partial x} \cos kx = i\hbar k\sin kx

which isn't equal to cos kx times a constant. The function \psi(x) = e^{ikx}, however, is an eigenfunction because you have

\hat{p}\psi(x) = \hbar k e^{ikx} = \hbar k \psi(x)

and the eigenvalue is \hbar k.
 
ok, that makes some sense, so since the position operator [x] is just x, then all of the functions are eigenfunctions...similarly, the potential energy operator is just the potential energy function. In this case the function is zero so since its =0 all the functions are eigen functions too right?
 
ok thanks, i think I have bridged the gap in my knowledge, one more quick question though...in Acos(kx)+iAsin(kx) the i doesn't play a role does it? I mean its just like a negative sign??
 
tarletontexan said:
ok, that makes some sense, so since the position operator [x] is just x, then all of the functions are eigenfunctions
No, that's not correct. For example, you have

\hat{x}(A \cos kx) = Ax\cos kx

That's not in the form of a constant multiplying the original function.
...similarly, the potential energy operator is just the potential energy function. In this case the function is zero so since its =0 all the functions are eigen functions too right?
 
wait, so x is the operator and if it multiplies times Acos(kx) or Acos(kx)+iAsin(kx) then wouldn't it be the same as multiplying x(psi)?
 
I'm not sure what you're asking. What's psi? Also, since you're using the same symbol for both the operator \hat{x} and variable x, you need to be clear which one you're using in your expressions.
 
\psi is psi, and i mean [x] times \psi would be [x]Acos(kx).
 
What does [x] mean?
 
  • #10
its the operator...
 
  • #11
Yes, applying the operator to a function results in the function multiplied by x (which isn't a constant).
 

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