Write down the time-independent Schrodinger equation and evaluate the corresponding solution for a free electron.

If Ψ1 is a solution to time-dependent Schrodinger equation and Ψ2 is a solution to the...

If Ψ1 is a solution to time-dependent Schrodinger equation and Ψ2 is a solution to the time dependent Schrodinger equation, then show that[aΨ1+ bΨ2] is also a solution to the time-dependent Schrodinger equation, with a and b arbitrary complex numbers.

Consider the Schrodinger equation and its solution for the hydrogen atom. a) Write an equation that...

Consider the Schrodinger equation and its solution for the hydrogen atom. a) Write an equation that would allow you to calculate, from the wavefunction, the radius of a sphere around the hydrogen nucleus within which there is a 90% probability of finding the electron. What is the radius of the same sphere if I want a 100% probability of finding the electron? b) Calculate the shortest wavelength (in nm) for an electronic transition. In what region of the spectrum is...

why can't we find a separable solution to the time dependent schrodinger equation if the Hamiltonian...

why can't we find a separable solution to the time dependent schrodinger equation if the Hamiltonian is a function of only time?

As you know, in the Schrodinger representation, the wavefunction is time-dependent while the operator is time-independent....

As you know, in the Schrodinger representation, the wavefunction is time-dependent while the operator is time-independent. In the Heisenberg representation, the wavefunction is time-independent while the operator is generally time-dependent. However, only the Hamiltonian is time-independent in both representations of Schrodinger and Heisenberg. Why? Describe the reason for that clearly.

1. Before reaching the double slit, the electron is described by the time-dependent Schrödinger equation (TDSE)...

1. Before reaching the double slit, the electron is described by the time-dependent Schrödinger equation (TDSE) for a freely moving particle. Starting with the time- independent Schrödinger equation (TISE), use separation of variables of the wave- function and the quantum energy relation to get the TDSE for a free particle.

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...

For the given differential equation; a) Evaluate the Homogeneous solution. b) Using the method of Variation...

For the given differential equation; a) Evaluate the Homogeneous solution. b) Using the method of Variation of Parameters only, evaluate the Particular Solution and write the Total Solution. ?′′(?)+ ??′(?)+??(?)=?−???? Must Show All Work & Simplify As Much As Possible

For the given differential equation, Must Show All Work a) Evaluate the Homogeneous Solution. b) Evaluate...

For the given differential equation, Must Show All Work a) Evaluate the Homogeneous Solution. b) Evaluate the Particular Solution. c) Evaluate the Total Solution. ??????+??=????+???−?? ?(?)=? ?′(?)=?

b. Write down a tree corresponding to Prufer sequence 11111, 12345, 54321.

b. Write down a tree corresponding to Prufer sequence 11111, 12345, 54321.

Evaluate: P(3,3) and at the same time enumerate the corresponding permutations of the objects from the...

Evaluate: P(3,3) and at the same time enumerate the corresponding permutations of the objects from the set {x, y, z}