A particle in the ground state of the quantum harmonic oscillator has a wavefunction that can be written as found in image where a = mω/hbar , and where N, m and ω are all constants. For this particle: a) Find an expression for the normalization constant N, in terms of a. b) Derive an expression for the uncertainty in the momentum, ∆p. N.B. You may wish to refer to the Appendix when answering this question.

A particle in the ground state of the quantum harmonic oscillator has a wavefunction that can be written as found in image where a = mω/hbar , and where N, m and ω are all constants. For this particle: a) Find an expression for the normalization constant N, in terms of a. b) Derive an expression for the uncertainty in the momentum, ∆p. N.B. You may wish to refer to the Appendix when answering this question.

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Question

A particle in the ground state of the quantum harmonic oscillator has a wavefunction that can be

written as

found in image

where a = mω/hbar , and where N, m and ω are all constants. For this particle:

a) Find an expression for the normalization constant N, in terms of a.
b) Derive an expression for the uncertainty in the momentum, ∆p.

N.B. You may wish to refer to the Appendix when answering this question.

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Step 1: Determine the given data:

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Step 2: a) Determine the normalization constant:

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Step 3: 2.b) Determine the uncertainty in momentum:

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Step 4: Determination of the uncertainty in momentum continued:

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please solve number 4
We will consider the Schrödinger equation in this problem as well as the analogies between the wavefunction and how boundary conditions are an essential part of developing this equation for various problems (situations). a) Write the form of the time-independent Schrödinger equation if the potential is that of a spring with spring constant k. Write the form of the time-dependent Schrödinger equation with the same potential. Briefly describe all the terms and variables in these equations. b) One solution to the time independent Schrödinger equation has the form Asin(kx). Why might it be called the wavefunction? If this form represents a wave of light, what is the energy for one photon? (Notek here stands for the wavevector and not the spring constant.) c) Why must all wavefunctions go to zero at infinite distance from the center of the coordinate system in all systems where the potential energy is always finite?
Answer all these questions
a) For a particle described by the wavefunction in Equation (1), show that the expectation values for momentum and momentum-squared are given by shown in image b) For the same particle, show that the expectation values for position and position-squared are given by shown in image
Subject is Physical Chemistry