5. We are going to add angular momenta h = 1 and j,--to form another basis...
Problem 1. (20 points) Consider two electrons, each with spin angular momentum s,-1/2 and orbital angular momentum ,-1. (a) (3 points) What are the possible values of the quantum number L for the total orbital angular momentum L-L+L,? (b) ( 2 points) What are the possible values of the quantum number S for the total spin angular momentum S-S,+S, (c) Points) Using the results from (a) and (b), find the possible quantum number J for the total angular momentum J-L+S....
5. Let S-S, + S2 + S, be the total angular momentum of three spin 1/2 particles (whose orbital variables will be ignored). Let | ε1, ε2, ε,' be the eigenstates common to Sla, S2t, ș3s, of respective eigenvalues 1 h/2, e2 h/2, E3ћ/2. Give a basis of eigenvectors common to S2 and S., in terms of the kets Ιει, ε2,E3 Do these two operators form a C.S.C.O.? (Begin by adding two of the spins, then add the partial angular...
(a) Use the states with total angular momentum 1-1, |1,1), |1,0), and 3. |1,-1), as a basis. Express L as a 3 x 3 matrix. (Ans: (b) Find the eigenvalues of L. (Ans: h, 0, -h.) (c) Express the corresponding eigenstates of L in terms of the states 1,1), |1,0), and |1,-1). (Ans: For eigenvalue h, the eigenstate is (1, 1) + V21,0) + 1, -1))/2. For eigenvalue 0, the eigenstate is (1, 1)-|1,-1))/V2. For eigenvalue -h, the eigenstate is...
1. In this problem, we are going to look at a three-level system. A spin-1 particld is placed in a constant magnetic field along the a-direction with strength B,. The spin-1 particle İs initialized in a z-eigenstate with positive eigenvalue h, ie, the i 1,m 1) state. What is the probability to find the negative eigenvalue the spin along the z axis as a function of time? Assume that the spin-1 particle has inagnetic moment 2 × μιι, i.e. that...
electromegnatic 22.2 EXERCISES 2-1 Show that 22-8) and (22-9) can also be -6 how that, in a li from (22-4) and (22-5) rather where P-0 and J,- Maxwell's equations first. be found completely fro and n by starting (22-4 an by going back to equation frst. t, if the free charge and current is, φ-, const. (zero is 1 equations determine N position and time, 227 Consider a re distributions and the polarization and ma gnetiza- tion are all given...
Instructions We're going to create a program which will allow the user to add values to a list, print the values, and print the sum of all the values. Part of this program will be a simple user interface. 1. In the Program class, add a static list of doubles: private statie List<double> _values new List<double>) this is the list of doubles well be working with in the program. 2. Add ReadInteger (string prompt) , and ReadDouble(string prompt) to the...
3 Angular Momentum and Spherical Harmonics For a quantum mechanical system that is able to rotate in 3D, one can always define a set of angular momentum operators J. Jy, J., often collectively written as a vector J. They must satisfy the commutation relations (, ] = ihſ, , Îu] = ihſ, J., ſu] = ihỈy. (1) In a more condensed notation, we may write [1,1]] = Žiheikh, i, j= 1,2,3 k=1 Here we've used the Levi-Civita symbol, defined as...
(3) Alan is jogging at a speed of 5 m/s at an angle of 120° with respect to the positive X-axiS. a)Write his velocity in component form. Write č in magnitude/angle form. Sketch the three vectors c Patricia is walking at 3 m/s such that the x component of her velocity is 1 m/s. Write her velocity in component form. What is its angle? (There are two possible solutions. Find both.) A helicopter flies upwards at a speed of 6.0...
Please write neatly and legibly. Please show all work. 1. Recall that given a basis, the space of linear endomorphisms of R", End (R"), can be identified with the space of nxn matrices. Let us denote this space by Mat (n). Clearly, with respect to standard addition of matrices and multiplication by scalars, Mat (n) is a na-dimensional vector space. 1. Let X e Mat (n). Then, we can think as being coordinates on Mat (n). 1,j=1...n Clearly, we must...
Problem 5. A 7.0kg bowling ball is hung to the ceiling via a 2.5 m steel wire. We move the ball horizontally, 10 cm away from the equilibrium position, and we start our chronometer when we let the ball go and it starts swinging. We model the system as an harmonic oscillator with elastic constant k expressed in terms of the mass of the ball m, the length 1 of the steel wire and g, the gravitational acceleration: k mg/l....