Plot ψ*ψ for an electron enclosed in a n infinite potential well for n =1-10. What...

An electron is trapped in an infinite square well potential of width 3L, which is suddenly...

An electron is trapped in an infinite square well potential of width 3L, which is suddenly compressed to a width of L, without changing the electron’s energy. After the expansion, the electron is found in the n=1 state of the narrow well. What was the value of n for the initial state of the electron in the wider well?

4. An electron is trapped in a one-dimensional infinite potential well of width L. (1) Find...

4. An electron is trapped in a one-dimensional infinite potential well of width L. (1) Find wavefunction ψn(x) under assumption that the wavefunction in 1 dimensional box whose potential energy U is 0 (0≤ z ≤L) is normalized (2) Find eighenvalue En of electron (3) If the yellow light (580 nm) can excite the elctron from n=1 to n=2 state, what is the width (L) of petential well?

An electron is in the ground state of an infinite square well. The energy of the...

An electron is in the ground state of an infinite square well. The energy of the ground state is E1 = 1.13 eV. (a) What wavelength of electromagnetic radiation would be needed to excite the electron to the n = 7 state? nm (b) What is the width of the square well? nm

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.

For the infinite square well we studied in class, you are given the following: Ψ(x,0) =...

For the infinite square well we studied in class, you are given the following: Ψ(x,0) = A(x/a) for 0<x<a/2 and Ψ(x,0) = A(1-x/a) for a/2<x<a and zero elsewhere. Calculate the probability of measuring a particular energy E_n. Verify that this probability makes sense.

1. As we increase the quantum number of an electron in a one-dimensional, infinite potential well,...

1. As we increase the quantum number of an electron in a one-dimensional, infinite potential well, what happens to the number of maximum points in the probability density function? It increases. It decreases. It remains the same 2. If an electron is to escape from a one-dimensional, finite well by absorbing a photon, which is true? The photon’s energy must equal the difference between the electron’s initial energy level and the bottom of the nonquantized region. The photon’s energy must...

A particle is trapped in an infinite potential well. Describe what happens to the particle’s ground-state...

A particle is trapped in an infinite potential well. Describe what happens to the particle’s ground-state energy and wave function as the potential walls become finite and get lower and lower until they finally reach zero (U = 0 everywhere).

Consider a particle trapped in an infinite square well potential of length L. The energy states...

Consider a particle trapped in an infinite square well potential of length L. The energy states of such a particle are given by the formula: En=n^2ℏ^2π^2 /(2mL^2 ) where m is the mass of the particle. (a)By considering the change in energy of the particle as the length of the well changes calculate the force required to contain the particle. [Hint: dE=Fdx] (b)Consider the case of a hydrogen atom. This can be modeled as an electron trapped in an infinite...

A particle is in the ground state of an infinite square well. The potential wall at...

A particle is in the ground state of an infinite square well. The potential wall at x = L suddenly (i.e., instantaneously) moves to x = 3L. such that the well is now three times its original size. (a) Let t = 0 be at the instant of the sudden change in the potential well. What is ψ(x, 0)? (b) If you measure the energy of the particle in the new well, what are the possible energies? (c) Estimate the...

For a particle in an infinite potential well the separation between energy states increases as n...

For a particle in an infinite potential well the separation between energy states increases as n increases. But doesn’t the correspondence principle require closer spacing between states as n increases so as to approach a classical (nonquantized) situation? Explain.