Winter wk 3, Thursday 20 Jan. 2011 Electrostatics & overview Div, Grad, and Curl Dirac Delta

1. Methods of Math. PhysicsDr. E.J. Zita, The Evergreen State CollegeLab II Rm 2272, zita@evergreen.edu • Winter wk 3, Thursday 20 Jan. 2011 • Electrostatics & overview • Div, Grad, and Curl • Dirac Delta • Modern Physics • Logistics: PIQs, e/m lab writeup

2. Electrostatics • Charges → E fields and forces • charges → scalar potential differences dV • E can be found from V • Electric forces move charges • Electric fields store energy (capacitance)

3. Magnetostatics • Currents → B fields • currents make magnetic vector potential A • B can be found from A • Magnetic forces move charges and currents • Magnetic fields store energy (inductance)

4. Electrodynamics • Changing E(t) → B(x) • Changing B(t) → E(x) • Wave equations for E and B • Electromagnetic waves • Motors and generators • Dynamic Sun

5. Some advanced topics • Conservation laws • Radiation • waves in plasmas, magnetohydrodynamics • Potentials and Fields • Special relativity

6. Del differentiates each component of a vector. Gradient of a scalar function = slope in each direction Divergence of vector = dot product = outflow Curl of vector = cross product = circulation = Differential operator “del”

7. Practice: 1.15: Calculate the divergence and curl ofv = x2x + 3xz2y - 2xz z Ex: If v = E, then div E ≈ charge. If v = B, then curl B ≈ current. Prob.1.16 p.18

8. 1.22 Gradient

9. 1.23 The  operator

10. 1.2.4 Divergence

11. 1.2.5 Curl

12. 1.2.6 Product rules

13. 1.2.7 Second derivatives Laplacian of scalar Lapacian of vector

14. Fundamental theorems For divergence: Gauss’s Theorem (Boas 6.9 Ex.3) For curl: Stokes’ Theorem(Boas 6.9 Ex.4)

15. Derive Gauss’ Theorem

16. Apply Gauss’ thm. to Electrostatics

17. Derive Stokes’ Theorem

18. Apply Stokes’ Thm. to Magnetostatics

19. Separation vector vs. position vector: Position vector = location of a point with respect to the origin. Separation vector: from SOURCE (e.g. a charge at position r’) TO POINT of interest (e.g. the place where you want to find the field, at r).

20. (separation vector) r’ r Point of interest, or Field point Source (e.g. a charge or current element) Origin See Griffiths Figs. 1.13, 1.14, p.9

22. Dirac Delta Function This should diverge. Calculate it using (1.71), or refer to Prob.1.16. How can div(f)=0? Apply Stokes: different results on L ≠ R sides! How to deal with the singularity at r = 0? Consider and show (p.47) that

23. Ch.2: Electrostatics: charges make electric fields • Charges → E fields and forces • charges → scalar potential differences • E can be found from V • Electrodynamics: forces move charges • Electric fields store energy (capacitance) F = q E = m a W = qV C = q/V

24. charges ↔ electric fields ↔ potentials

25. Gauss’ Law practice: What surface charge density does it take to make Earth’s field of 100V/m? (RE=6.4 x 106 m) 2.12 (p.75) Find (and sketch) the electric field E(r) inside a uniformly charged sphere of charge density r. 2.21 (p.82) Find the potential V(r) inside and outside this sphere with total radius R and total charge q. Use infinity as your reference point. Compute the gradient of V in each region, and check that it yields the correct field. Sketch V(r).

26. Curl of vector = cross product = circulation Curl