An electron (mass m) is trapped ina 2-dimensional infinite square box of sides Lx - L...
An electron is trapped in an infinite square-well potential of width 0.3 nm. If the electron is initially in the n = 4 state, what are the various photon energies that can be emitted as the electron jumps to the ground state? (List in descending order of energy. Enter 0 in any remaining unused boxes.) highest eV eV eV eV eV lowest eV
Suppose that an electron trapped in a one-dimensional infinite well of width 118 pm is excited from its first excited state to the state with n = 8. (a) What energy (in eV) must be transferred to the electron for this quantum jump? The electron then de-excites back to its ground state by emitting light, In the various possible ways it can do this, what are the (b) shortest, (c) second shortest, (d) longest, and (e) second longest wavelengths (in...
DApdr Q2. An electron is trapped in an one dimensional infinite potential well of length L Calculate the Probability of finding the electron somewhere in the region 0 <xLI4. The ground state wave function of the electron is given as ㄫㄨ (r)sin (5 Marks) O lype hene to search
4. (20 points) Infinite Wells in Three Dimensions a) Consider a three dimensional in- finite rectangular well for which L -L, Ly-2L, ald L2-3L. In terms of quantum numbers (e.g. nz, ny, and n.), M. L, and ћ. write down an expression for the energies of all quantum states. (b) Find the energies of the ground state and the first three lowest lying energies. As in part (b), for each energy level, give the quantum numbers n, ny, n and...
Given a 3-dimensional particle-in-a-box system with infinite barriers and Lx=5nm, Ly=5nm and Lz=6nm. Calculate the energies of the ground state and first excited state. List all combinations of values for the quantum numbers nx, ny and nz that are associated with these states.
Suppose that an electron is trapped in a one- dimensional, infinite potential well of width 250 nm is excited from the 2nd excited state to the fifth excited state. What energy must be transferred to the electron in order to make this transition? Answer: 1.62 x 10^-4 eV Check Correct Marks for this submission: 2.00/2.00. What wavelength photon does this correspond to? Answer: 75.15*10^-4m Check Considering all of the possible ways that the excited electron can de-excite back down to...
1/2) confined in a one-dimensional rigid box (an infinite Imagine an electron (spin square well). What are the degeneracies of its energy levels? Make a sketch of the lowest few levels, showing their occupancy for the lowest state of six electrons confined in the same box. Ignore the Coulomb repulsion among the electrons. (6 points) S = 1/2) confined in a one-dimensional rigid box (an infinite Imagine an electron (spin square well). What are the degeneracies of its energy levels?...
5. (25 pts) An electron is trapped inside a rigid box of length L-0.250nm. a) If the electron is initially in the second excited state, what is the wavelength of the emitted photon if the electron jumps to the ground state? b) The wavefunction for the electron in its first excited state is given by-(x)fsin2m excited state is given by ψ(x)--sin what is the probability of finding the electron in the middle region of the rigid box, srsc) Sketch the...
Problem 2: Infinite Square Well III (7 marks) An electron is confined to an infinite square well, which spans from x = 0 to x- a. Initially, the electron is in an equal linear superposition of the ground and first excited state of the quantum well with zero relative phase. (a) [1 mark] Write down the initial wavefunction Ψ(x, t = 0) of the electron in terms of the energy eigenfunctions. (b) [1 mark] Plot the initial PDF for an...
An electron is trapped in a one-dimensional infinite well and is in its first excited state. The figure indicates the five longest wavelengths of light that the electron could absorb in transitions from this initial state via a single photon absorption: λa = 81.5 nm,λb = 31.1 nm,λc = 19.5 nm,λd = 12.6 nm, and λe = 7.83 nm. What is the width of the potential well? III-(nm)