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An infinitely large plate has uniform surface charge density +o where o is a positive number. The plate moves with speed v along the x-direction. Since the charges are moving with the plate, they form a uniform two dimensional surface current density K whose value is |K| by a line of length L is I = |K|L. See Fig. 2(A) below. = ov. Namely, the electric current I passing (A) K X (B) (C) +o V V Ampere loop FIGURE 2 (a) By symmetry, the value of magnetic field B due to the current K above or below the plate is the same, and B is obviously parallel to the plate. In which direction is B pointing above the plate? Below the plate? (b) Find the value of the magnetic field B above or below the plate by Ampere's law, using the rectan- gular Ampere loop shown in the Fig. 2(B). Again, by symmetry, the values of B must be the same above or below the plate, and it must be a constant that only depends on |K| and v. Hint: Compute S B · dl´along the four segments of the Ampere loop and pay attention if B || dl´or BIdl on each of the four segments. (c) Now, suppose you have two parallel infinitely large plates, but one with +o charge density and the other with -o charge density, see Fig. 2(C). Both move with speed v along the x-direction. What is the magnetic field in between the two plates? (d) A positive point charge q enters in between the plates and moves in the +x-direction with speed vg. Determine the force on q due to the magnetic field. (e) Now, the two plates stop moving (v = 0), but for some strange reason the value of charge density on both plates reduces with time t: o = 0,e-at where a and o, are positive constants. Calculate the displacement current density in the space between the two plates. -------