Point P lies between two parallel infinite lines of charge, which have charge densities 11 = (-8.939x10^O) µC/m and A2 = (3.055x10^0) µC/m respectively. Point P is at a distance R1 = (3.2630x10^0) cm from line 1, and R2 (6.92x10^0) cm from line 2. Calculate the net electric field at Point P in N/C. You do not need to enter a unit vector in your answer, but a negative sign is needed if the electric field points along the negative x-axis. +X r2 P.
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- Figure 4 shows a section of a long, thin-walled solid infinitely long metal tube of radius R = 5.00 cm , with a charge per unit length of λ = 2.00 ×10−8C/m . What is the magnitude of the electric field at radial distanceA solid sphere of radius 40.0 cm has a total positive charge of 31.7 µC uniformly distributed throughout its volume. Calculate the magnitude of the electric field at the following distances. (a) 0 cm from the center of the sphere 0 ✓ kN/C (b) 10.0 cm from the center of the sphere 445.78 kN/C ✓ (c) 40.0 cm from the center of the sphere 1783.12 ✓ kN/C (d) 59.0 cm from the center of the sphere kN/C Need Help? Read It Watch ItA thin, metallic, spherical shell of radius a = 5.0 cm has a charge qa = 4.00×10-6 C. Concentric with it is another thin, metallic, spherical shell of radius b = 10.00 cm and charge qb = 6.00×10-6 C. a) Find the electric field at radial points r where r = 0.0 cm. b)Find the electric field at radial points r where r = 7.5 cm. c)Find the electric field at radial points r where r = 15.0 cm. d)Discuss the criterion one would use to determine how the charges are distributed on the inner and outer surface of the shells. What is the charge on the outer surface of the outer shell?
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