Consider the three-dimensional harmonic oscillator. Indicate the energy of the base state if twelve identical particles...

Consider a system of three non-interacting particles confined by a one-dimensional harmonic oscillator potential and in...

Consider a system of three non-interacting particles confined by a one-dimensional harmonic oscillator potential and in thermal equilibrium with a total energy of 7/2 ħw. (a) what are the possible occupation numbers for this system if the particles are distinquishable. (b) what is the most probable energy for a distinquishable picked at random from this system.

Consider an electron bound in a three dimensional simple harmonic oscillator potential in the n=1 state....

Consider an electron bound in a three dimensional simple harmonic oscillator potential in the n=1 state. Recall that the e- has spin 1/2 and that the n=1 level of the oscillator has l =1. Thus, there are six states {|n=1, l=1, ml, ms} with ml= +1, 0, -1 and ms = +/- 1/2. - Using these states as a basis find the six states with definite j and mj where J = L +s - What are the energy levels...

Find the energy levels, the base state's wave function, and the first excited state for a...

Find the energy levels, the base state's wave function, and the first excited state for a system of two identical particles in an infinite unidimensional potential well that don't interact. a) if both particles have spin 1 b) if they have spin ½

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

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

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.

Description: I am studying the chapter of Identical Particles for QM. My instructor only shown me...

Description: I am studying the chapter of Identical Particles for QM. My instructor only shown me how to deal with square wells, I was wondering about the Harmonic Oscillator. Is it still the similar treatment like Infinite Square Wells? Please help me solve the problem I create. I am new on this chapter so please SHOW ALL YOUR STEPS and be as concise as possible ! Problem: Three particles are confined in a 1-D harmonic oscillator potential. Determine the energy...

Consider a one dimensional Harmonic oscillator. Use perturbation theory to find the energy corrections up to...

Consider a one dimensional Harmonic oscillator. Use perturbation theory to find the energy corrections up to second order in the perturbative parameter ? for a perturbative potential of the kind: a) V = ?x b) V = ?x^3.

A system of 6 identical 1-dimensional harmonic oscillators (it could be two atoms of an Einstein...

A system of 6 identical 1-dimensional harmonic oscillators (it could be two atoms of an Einstein model solid). What is the probability that the first oscillator has 2 quanta of vibrational energy when the system has 3 quanta of vibrational energy? Hint: You may find it useful to consider how many microstates the system has and how many microstates the rest of the system has when the first oscillator has 2 quanta. Answer is 5/56 For the system considered in...

Quantum mechanics: Consider a particle initially in the ground state of the one-dimensional simple harmonic oscillator....

Quantum mechanics: Consider a particle initially in the ground state of the one-dimensional simple harmonic oscillator. A uniform electric field is abruptly turned on for a time t and then abruptly turned off again. What is the probability of transition to the first excited state?