Consider 3 identical bosons in a one dimensional infinitely deep well of width 2a. A.) What...

An infinitely deep square well has width L = 2.5 nm. The potential energy is V...

An infinitely deep square well has width L = 2.5 nm. The potential energy is V = 0 eV inside the well (i.e., for 0 ≤ x ≤ L). Seven electrons are trapped in the well. 1) What is the ground state (lowest) energy of this seven electron system in eV? Eground = 2) What is the energy of the first excited state of the system in eV? NOTE: The first excited state is the one that has the lowest...

An electron is trapped in an infinite one-dimensional well of width = L. The ground state...

An electron is trapped in an infinite one-dimensional well of width = L. The ground state energy for this electron is 3.8 eV. a) Calculated energy of the 1st excited state. b) What is the wavelength of the photon emitted between 1st excited state and ground states? c) If the width of the well is doubled to 2L and mass is halved to m/2, what is the new 3nd state energy? d) What is the photon energy emitted from the...

Suppose that an electron trapped in a one-dimensional infinite well of width 0.341 nm is excited...

Suppose that an electron trapped in a one-dimensional infinite well of width 0.341 nm is excited from its first excited state to the state with n = 5. 1 What energy must be transferred to the electron for this quantum jump? 2 The electron then de-excites back to its ground state by emitting light. In the various possible ways it can do this, what is the shortest wavelengths that can be emitted? 3 What is the second shortest? 4 What...

Find the wave function for the ground state and first two excited states for a particle...

Find the wave function for the ground state and first two excited states for a particle in an infinitely deep square well of width a. Show that the uncertainty relation is satisfied for position and momentum.

Given three non-interacting distinguishable in an infinite 1-D square well potential of width a. (a) Determine...

Given three non-interacting distinguishable in an infinite 1-D square well potential of width a. (a) Determine the ground wave function for the system of distinguishing and the energy of this state. (b) Determine the wave function of the first excited state and its energy.

Consider a three dimensional rectangular infinite potential well with sides of length L, 2L and 3L....

Consider a three dimensional rectangular infinite potential well with sides of length L, 2L and 3L. What is the energy of the first excited state relative to the energy of the ground state? What is the energy of the second excited state relative to the energy of the ground state? What is the energy of the third excited state relative to the energy of the ground state? What is the energy of the fourth excited state relative to the energy...

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...

4. Write down the time-independent Schrӧdinger Equation for two non-interacting identical particles in the infinite square...

4. Write down the time-independent Schrӧdinger Equation for two non-interacting identical particles in the infinite square well. Assuming the spins of the two particles are parallel to each other, i.e., all spin-up, find the normalized wave function representing the ground state of the two-particle system and the energies for the two cases: (a) Two particles are identical bosons. (b) Two particles are identical fermions. and (c) Find the wave functions and energies for the first and second excited states for...

An electron is in an infinite one-dimensional square well of width L = 0.12 nm. 1)...

An electron is in an infinite one-dimensional square well of width L = 0.12 nm. 1) First, assume that the electron is in the lowest energy eigenstate of the well (the ground state). What is the energy of the electron in eV? E = 2) What is the wavelength that is associated with this eigenstate in nm? λ = 3) What is the probability that the electron is located within the region between x = 0.048 nm and x =...

A neutron is trapped in an infinitely deep potential well 1.6 fm in width. A) Determine...

A neutron is trapped in an infinitely deep potential well 1.6 fm in width. A) Determine the four lowest possible energy states. [Note: This is a rough model of an atomic nucleus. E1, E2, E3, E4 =    MeV   B) What is the energy of a photon emitted when the neutron makes a transition between the two lowest states?E =   MeV   C) What is the wavelength of this photon? in m D) In what region of the EM spectrum does this photon lie?