(a) Give the parities of the wavefunctions for the first four levels of a harmonic oscillator....

a. Based on the parity of the wavefunctions, explain why〈?〉? = 0 for any states of...

a. Based on the parity of the wavefunctions, explain why〈?〉? = 0 for any states of a 1-D Harmonic Oscillator without explicit integral evaluation. b. Based on the parity of the wavefunctions, explain why〈??〉? = 0 for any states of a 1-D Harmonic Oscillator without explicit integral evaluation.

Assume that the hydrogen molecule behaves exactly like a harmonic oscillator with a force constant of...

Assume that the hydrogen molecule behaves exactly like a harmonic oscillator with a force constant of 573 N/m. (a) Calculate the energıas, in eV's, of the fundamental and first excited state. (b) Find the vibrational quantum number that roughly corresponds to your energy

Consider a harmonic oscillator. What is the relationship between the number of nodes and the vibrational...

Consider a harmonic oscillator. What is the relationship between the number of nodes and the vibrational energy level, as characterized by the vibrational quantum number?

Find the eigenstates and energies for a 3-D quantum harmonic oscillator as we did for the...

Find the eigenstates and energies for a 3-D quantum harmonic oscillator as we did for the 3-D infinite square well case. In both cases there are 3 distinct n values with a label for the x, y, or z coordinate. Compare the degeneracies of the first 3 distinct energy levels of these two systems.

For the simple harmonic oscillator at first excited state the Hermite polynomial H1=x, (a)find the normalization...

For the simple harmonic oscillator at first excited state the Hermite polynomial H1=x, (a)find the normalization constant C1 (b) <x> (c) <x2>, (d) <V(x)> for this state.

Q. 2​(a) For the first excited state of harmonic oscillator, calculate <x>, <p>, <x2>, and <p2>...

Q. 2​(a) For the first excited state of harmonic oscillator, calculate <x>, <p>, <x2>, and <p2> explicitly by spatial integration. (b) Check that the uncertainty principle is obeyed. (c) Compute <T> and <V>. .

In Classical Physics, the typical simple harmonic oscillator is a mass attached to a spring. The...

In Classical Physics, the typical simple harmonic oscillator is a mass attached to a spring. The natural frequency of vibration (radians per second) for a simple harmonic oscillator is given by ω=√k/m and it can vibrate with ANY possible energy whatsoever. Consider a mass of 135 grams attached to a spring with a spring constant of k = 1 N/m. What is the Natural Frequency (in rad/s) of vibration for this oscillator? In Quantum Mechanics, the energy levels of a...

A harmonic oscillator with mass m and force constant k is in an excited state that...

A harmonic oscillator with mass m and force constant k is in an excited state that has quantum number n. 1) Let pmax=mvmaxx, where vmax is the maximum speed calculated in the Newtonian analysis of the oscillator. Derive an expression for pmax in terms of n, ℏ, k, and m. Express your answer in terms of the variables n, k, m, and the constant ℏ 2) Derive an expression for the classical amplitude A in terms of n, ℏ, k,...

1) A quantum harmonic oscillator with frequency ωcontains 41 electrons. What is the energy of the...

1) A quantum harmonic oscillator with frequency ωcontains 41 electrons. What is the energy of the highest-energy electron? Assume that the electrons are in the lowest states possible. 2 a) An atom has a total of 18 electrons. What is the principal quantum number of the outermost shell? 2 b) How many electrons does the outermost shell shell contain? 3) Which of the following represents the possible range of integer values for the magnetic quantum number? a) 1 to l...

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and...

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and there are eight spin 1⁄2 particles in the oscillator. How much energy is needed to add a ninth electron. Explain and show your work.