Straight-forward quantum question

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SUMMARY

The discussion focuses on a quantum mechanics problem involving a particle of mass m confined by a Gaussian potential, V(x) = -V0*exp(-x^2/a^2). The participants explore the characteristics of the wavefunctions for the ground state and the first excited state, emphasizing the need for the total energy E to be less than the potential V for bound states. The conversation highlights the challenge of determining the wavefunctions without directly solving the Schrödinger equation, prompting questions about the relationship between the potential and the excited states.

PREREQUISITES
  • Understanding of quantum mechanics principles, particularly bound states
  • Familiarity with Gaussian potentials in quantum systems
  • Knowledge of the Schrödinger equation and its implications
  • Concept of wavefunction parity and asymptotic behavior
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  • Research the properties of Gaussian potentials in quantum mechanics
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Students and educators in quantum mechanics, physicists interested in potential theory, and anyone studying wavefunction characteristics in quantum systems.

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Homework Statement



A particle of mass m is confined by a 1-dimensional potential of the form V(x) = -V0*exp(-x^2/a^2). Assume that V0 is large enough that there are at least two bound states. Sketch the wavefunction of the ground state and the first excited state, clearly indicating the parity and asymptotic behavior of each. You are not asked here to solve the Schroedinger equation.

Homework Equations





The Attempt at a Solution



Ok... so the potential is a Gaussian.

Since the potential is not infinite, we need the total energy E to be less than V to have a bound state (right)?

My questions is: is the first excited state just the derivative of V? I guess it's not clear to me how to deal with this without solving for solutions, unless there's a simple relationship between the potential and the first excited state. The only way I can really think of doing this is to solve H*psi = E*psi, apply boundary conditions, and see what solutions I have. But I'm supposed to do this without solving that equation...
 
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What do the solutions to, say, the simple harmonic oscillator look like as you increase the energy? Why do they look this way? Are there any patterns they follow that might be true in general?
 

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