A solid sphere of radius a, centered at the origin, carries a volume charge density of p(r) = ar², where a is a constant (see Fig. 2 below). a. Calculate the electric field inside and outside of the sphere. (NOTE: For a spherically symmetric system, dV = r² sin(e) de dødr. Therefore, the volume integral of some function p(x) is given by fp(r)r² sin(e) de dødr = 4n fp(r)r² dr) b. Plot the resulting electric field as a function of distance r from the origin.

A solid sphere of radius a, centered at the origin, carries a volume charge density of p(r) = ar², where a is a constant (see Fig. 2 below). a. Calculate the electric field inside and outside of the sphere. (NOTE: For a spherically symmetric system, dV = r² sin(e) de dødr. Therefore, the volume integral of some function p(x) is given by fp(r)r² sin(e) de dødr = 4n fp(r)r² dr) b. Plot the resulting electric field as a function of distance r from the origin.

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2.6
The classic Millikan oil drop experiment was the first to obtain an accurate measurement of the charge on an electron. In it, oil drops were suspended against the gravitational force by a vertical electric field. 1a. Given the oil drop to be 0.99 μm in radius and have a density of 910 kg/m3: Find the weight of the drop. 1b.If the drop has a single excess electron, find the electric field strength needed to balance its weight. This is not and will not be graded
Need help with part B pls
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Solve 4,5
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Both of them, please.
1. Find the electric field a distance : above one end of a straight length of wire of length 2L (Fig. 2.8). Assume that the wire carries uniform line charge A. After Griffiths, problem 2.3 2L 2. Determine the electric field a distance z above the center of a large square loop of side a, if it carries a unikorm charge A. You may use the result for the electric field at a distance z above a midpoint of a straight wire with constant A. After Griffiths, problem 2.4. 3. The electric field in a region of space described in spherical co-ordinates, is given by E(F) = r + sin o sin deos 00 + sin ở cos dop, where A and B are constants. (a) Calculate V xỂ. (b) Determine the charge density at the point (1,45). 4 (a) Using Gauss's law, calculate the electric field at a point distant s from a long wire bearing uniform charge density A.