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

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?

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

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

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.

The state of a particle is completely described by its wave function Ψ(?,?) One-dimensional Schrodinger Equation--...

The state of a particle is completely described by its wave function Ψ(?,?) One-dimensional Schrodinger Equation-- answer the following questions: 2) Show that when U(x) = 0, and , is a solution to the one-?=2??/ℏΨ=?sin??dimensional Schrodinger equation. 3) Show that when U(x) = 0, and , is a solution to the one-?=2??/ℏΨ=?cos??dimensional Schrodinger equation. 4) Show that where A and B are constants is a solution to the Ψ=??+?Schrodinger equation when U(x) = 0, and when E = 0.

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...

A particle in a strange potential well has the following two lowest-energy stationary states: ψ1(x) =...

A particle in a strange potential well has the following two lowest-energy stationary states: ψ1(x) = C1 sin^2 (πx) for − 1 ≤ x ≤ 1 ψ2(x) = C2 sin^2 (πx) for − 1 ≤ x ≤ 0 ψ2(x) = −C2 sin^2 (πx) for 0 ≤ x ≤ 1 The energy of ψ1 state is ¯hω. The energy of ψ2 state is 2¯hω. The particle at t = 0 is in a superposition state Ψ(x, t = 0) = 1/√...

Show for stationary eigenstates of the Schrodinger equation in one dimension. Qualitatively explain why the eigenfunction...

Show for stationary eigenstates of the Schrodinger equation in one dimension. Qualitatively explain why the eigenfunction ψ(x) is smooth, i.e., its first derivative dψ/dx is continuous, even when the potential V (x) has a discontinuity (a finite jump). Hints: use the delta function

Show for stationary eigenstates of the Schrodinger equation in one dimension. When the potential has inversion...

Show for stationary eigenstates of the Schrodinger equation in one dimension. When the potential has inversion symmetry, V (x) = V (−x), parity is conserved in bound states: the eigenfunction is either even (ψ(x) = ψ(−x)) or odd (ψ(x) = −ψ(−x)) under parity transformation, x → −x.

A nonhomogeneous equation and a particular solution are given. Find a general solution for the equation....

A nonhomogeneous equation and a particular solution are given. Find a general solution for the equation. y''+5y'+6y=24x^(2)+40x+8+12e^(x), y_p(x)=e^(x)+4x^(2) The general solution is y(x)= ​(Do not use​ d, D,​ e, E,​ i, or I as arbitrary constants since these letters already have defined​ meanings.)

Consider the full time-dependent wavefunctions Ψ(x, t) = ψ(x)φ(t). For the case of an infinite square...

Consider the full time-dependent wavefunctions Ψ(x, t) = ψ(x)φ(t). For the case of an infinite square well in 1D, these were Ψn(x, t) = Sqrt (2/L) sin(nπx/L) e^(−i(En/h)t In general, the probability density |Ψn|2 is time-independent. But suppose instead of being ina fixed energy state, we are in a special state Ψmix(x, t) = √12(Ψ1 − iΨ2). What is the time-dependent part of |Ψmix|2?