A solid sphere of radius A has a uniform charge density per unit volume ρ and a total charge Q. Express the result for E(r) for 0 ≤ r ≤ a in terms of Q and a instead of ρ, and make a sketch of E(r) showing its behavior over both the ranges 0 ≤ r ≤ a and r ≥ a. (b) Place a particle with charge +q0 at a distance r1 > a from the center of the sphere. What is the work W1 done by the Coulomb force on the particle as the particle moves from r=r1 tor=∞? (c)(Numeric)IfQ=1μC, q0 =10nC, a=0.05m, andr1 =0.2m, computeW1 basedon your result to part (b). [Ans. W1 = 4.5 × 10−4 Joules.] (d) Using the expression for change in potential energy ∆U = −W, and the convention that U(+∞) = 0, obtain the expression U(r) for the potential energy of the charge q0 as a function of the distance r from the center of the sphere, for r ≥ a. (e) Recalling the definition of the electric potential V , write down the expression for V (r) due to the sphere for r ≥ a. (f) (Numeric). Using the same numerical values given in part (c), calculate the electric potential V (r = a) due to the sphere at the surface of the sphere. [Ans. V (r = a) = 1.8×105 Volts.] (g) Now, supposing the charge q0 starts from a position r2 < a, compute the work W2 done by the electric field inside the sphere in moving the charge q0 from r = r2 to the edge of the sphere at r = a. (h) (numeric) If r2 = 0.03 m, compute W2 using the other numerical values from part (b). [Ans: W2 = 5.8 × 10−4 Joules.] (i) Again, using the expression for change in potential energy ∆U = −W , and the convention that U(+∞) = 0, obtain the expression U(r) for the potential energy of the charge q0 as a function of the distance r from the center of the sphere, for r ≤ a. Write down the corresponding expression for V (r) in this same range. Is the electric potential higher inside the sphere than outside? (j) Using the numerical values we’ve been using, make computer generated plots of V (r) overtheranges0≤r≤aanda≤r≤5a. LookattheshapeofV(r)asr→0. Isit consistent with the electric field being zero at t