1. Consider a particle with mass m in a one dimensional potential V (x) = A/x...

particle of mass m is moving in a one-dimensional potential V (x) such that ⎧ ⎨...

particle of mass m is moving in a one-dimensional potential V (x) such that ⎧ ⎨ mω2 x2 ifx>0 V (x) = 2 ⎩ +∞ if x ≤ 0 (a) Consider the motion classically. What is the period of motion in such potential and the corresponding cyclic frequency? (b) Consider the motion in quantum mechanics and show that the wave functions of the levels in this potential should coincide with some of the levels of a simple oscillator with the...

Consider a spinless particle of mass m, which is moving in a one-dimensional infinite potential well...

Consider a spinless particle of mass m, which is moving in a one-dimensional infinite potential well with walls at x = 0 and x = a. If and are given in Heisenberg picture, how can we find them in Schrodinger and interaction picture?

Consider a particle of mass m and energy E approaching the step potential? V (x)= 0,...

Consider a particle of mass m and energy E approaching the step potential? V (x)= 0, x<0    V(x)=V0, x>0 from negative values of x. Consider the case E > V0. a) Classically, what is the probability of re?ection? b) Quantum mechanically, what is the probability of re?ection? Express your result in terms of the ratio V0/E. What is the probability of re?ection if E = 2V0?

Exercise 3. Consider a particle with mass m in a two-dimensional infinite well of length L,...

Exercise 3. Consider a particle with mass m in a two-dimensional infinite well of length L, x, y ∈ [0, L]. There is a weak potential in the well given by V (x, y) = V0L2δ(x − x0)δ(y − y0) . Evaluate the first order correction to the energy of the ground state.    Evaluate the first order corrections to the energy of the first excited states for x0 =y0 = L/4. For the first excited states, find the points...

A particle of mass m moves in a one-dimensional box of length L, with boundaries at...

A particle of mass m moves in a one-dimensional box of length L, with boundaries at x = 0 nm and x = 5 nm. Thus, V (x) = 0 for 0 ≤ x ≤ 5 nm, and V (x) = ∞ elsewhere. a) Can light excite a particle from its ground state to the fourth excited state? Mathematically support your answer. b) If the optical transition in (a) is possible, what is the required wavelength of light that generates...

Consider two particles of mass m connected by a spring with rest length L with potential...

Consider two particles of mass m connected by a spring with rest length L with potential energy given by V(x1, x2) = ½ k (x1 – x2 – L)2. Show that the total wavefunction for this system is the product of two terms, one term is the solution for free particle motion of the center of mass for a particle with the total mass and the other term is simple harmonic (vibrational) motion of the relative displacement x1-x2 of the...

II(20pts). Short Problems a) The lowest energy of a particle in an infinite one-dimensional potential well...

II(20pts). Short Problems a) The lowest energy of a particle in an infinite one-dimensional potential well is 4.0 eV. If the width of the well is doubled, what is its lowest energy? b) Find the distance of closest approach of a 16.0-Mev alpha particle incident on a gold foil. c) The transition from the first excited state to the ground state in potassium results in the emission of a photon with  = 310 nm. If the potassium vapor is...

URGENT (need within 1.5 hour) A particle of mass M is confined to move in the...

URGENT (need within 1.5 hour) A particle of mass M is confined to move in the x-y plane, and is subjected to the following potential V(x,y) = 1⁄2 k1 x2 + 1⁄2 k2 y2 where k1 and k2 are the spring constants restricting the motion, and k1 << k2. (a) Write down the Schrodinger equation for the particle, and show the steps to solve the equation, assuming the solution of the one-dimensional Harmonic oscillator is known. (b) Write down the...

4. Consider a free electron bound within a 2-dimensional infinite potential well defined by V =...

4. Consider a free electron bound within a 2-dimensional infinite potential well defined by V = 0 for 0 < x < 25 Å, 0 < y < 50 Å, and V = ∞ elsewhere. Determine the expression for the allowed electron energies.

A particle is confined to the one-dimensional infinite potential well of the figure. If the particle...

A particle is confined to the one-dimensional infinite potential well of the figure. If the particle is in its ground state, what is the probability of detection between x = 0.20L and x = 0.65L?