1. Derive the wavefunction for Hydrogen in Ground State For Q1, find the probability distribution for...
10. The radial portion of the wavefunction for an electron in the ground state of the hydrogen atom is Vso)-1/(2 exp(-r/ao) where do is the Bohr radius. Calculate the expectation value of r. we Know 10 pts
Problem 10 (Problem 2.24 in textbook) The wavefunction for the electron in a hydrogen atom in its ground state (the 1s state for which n 0, l-0, and m-0) is spherically symmetric as shown in Fig. 2.14. For this state the wavefunction is real and is given by exp-r/ao h2Eo 5.29 x 10-11 m. This quantity is the radius of the first Bohr orbit for hydrogen (see next chapter). Because of the spherical symmetry of ịpo, dV in Eq. (2.56)...
(a) Find (r) and (r2) for an electron in the ground state of hydrogen. Express your answers in terms of the Bohr radius a. If a measurement on r is performed for the ground state wavefunction, what is the most probable value? (b) Find (x) and (x2) for an electron in the ground state of hydrogen. Hint: This requires no new integration-note that r2 = x2 + y2 + z2, and exploit the symmetry of the ground state.
(1) The ground-state wave function for the electron in a hydrogen is given by ls 0 Where r is the radial coordinate of the electron and a0 is the Bohr radius (a) Show that the wave function as given is normalized (b) Find the probability of locating the electron between rF a0/2 and r2-3ao/2. Note that the following integral may be useful n! 0 dr =-e re /a roa r a Ta
(VI) Hydrogen atom A What is the probability that an electron in the ground state of hydrogen will be found inside the nucleus? Find the expression for the probability, in which Rc denotes the the radius of nucleus. Hints: Rc IT 127 i) Integration in spherical coordinate system (r, 0, 0)|r2 sin Ododedr Jo Jo Jo 2.c 20 e Jo a 2 B Construct the wavefunction for an electron in the state defined by the three quantum numbers: principal n...
1) (60 points) The ground state of the hydrogen atom: In three dimensions, the radial part of the Schrodinger equation appropriate for the ground state of the hydrogen atom is given by: ke2 -ħ2 d2 (rR) = E(rR) 2me dr2 where R(r) is a function of r. Here, since we have no angular momentum in the ground state the angular-momentum quantum number /=0. (a) Show that the function R(r) = Ae-Br satisfies the radial Schrodinger equation, and determine the values...
Calculate the radial probability density P(r) for the hydrogen atom in its ground state at (a)r=0 and (b) r= 2.75a, where a is the Bohr radius. (a) Numberto (b) Number 13.65E10 unitesimm-1 units nm-1
Calculate the probability of an electron in the ground state of the hydrogen atom being inside the region of the proton. (For purposes of calculation, use a proton radius r = 0.960 x 105 m. Hint: Note that r << an.) X
for an electron in a Hydrogen atom: 2) Consider the electron in a 2p state (for simplicity, take M = 0) (i) Consider whether <r> and <1/r> can be calculated by integrating only the radial part of the wavefunction. (ii) Calculate the expectation value of the distance between the electron and the nucleus, (ii) Calculate the expectation value of the reciprocal distance between the electron and the nucleus, <1/r>. (iv) Are the average potential energies of the electron in 2s...
1. Given the following wavefunction for the ground state of a finite quantum well of width 2nm, ground state energy of E1=0.05eV -A cos(kx) and ψ,-Beax A.) Find the values of k and a (remember to keep the wavefunction continuous and smooth)[10ptsl B.) Find the normalization constants A and B (you will need to find k first of course) [10pts] C.) Determine the barrier energy from the decay constant a? [5pts D.)If the well were replaced with a semi-infinite well...