•23 (a) Figure 24-42a shows a nonconducting rod of length L = 6.00 cm and uniform linear charge density A = +3.68 pC/m. Assume that the electric potential is defined to be V = 0 at infinity. What is V at point P at distance d = 8.00 cm along the rod's perpendicular bi- sector? (b) Figure 24-42b shows an identical rod except that one half is now negatively charged. Both halves have a linear charge density of magnitude 3.68 pC/m. With V = 0 at infinity, what is V at P? – 1/2 L/2- -L/2 L/2- (a) (b)

•23 (a) Figure 24-42a shows a nonconducting rod of length L = 6.00 cm and uniform linear charge density A = +3.68 pC/m. Assume that the electric potential is defined to be V = 0 at infinity. What is V at point P at distance d = 8.00 cm along the rod's perpendicular bi- sector? (b) Figure 24-42b shows an identical rod except that one half is now negatively charged. Both halves have a linear charge density of magnitude 3.68 pC/m. With V = 0 at infinity, what is V at P? – 1/2 L/2- -L/2 L/2- (a) (b)

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Similar questions

Please answer question 34
A metal sphere of radius 13 cm has a net charge of 4.0 x 10-8 c. (a) What is the electric field at the sphere's surface? (b) If V = 0 at infinity, what is the electric potential at the sphere's surface? (c) At what distance from the sphere's surface has the electric potential decreased by 560 V? (a) Number i Units (b) Number i Units (c) Number i Units >
P₁ D J P2 ZFF- \d+|- L Figure 24-34 Problems 33, 34, and 51.
Point charges q, = 35 µC, q,= -25 µC, and q3 = 15 µC are located in Figure 1. A rod with length L=2 m has a total charge q=90 µC and a uniform linear charge density 2=45 µC/m in Figure 2. (a) Find the potential at P in Figure 1. (b) Find the total potential energy of charge system in Figure 1. |(c) Find the total potential at P in Figure 2. (k = 9×10° N×m²/C², and µ= 10-6) λ-45 μC/m q1 = 35 µC Qι-35 μC + L = 2 m |0.3 m 0.5 m 0.3 m 93 = 15 µC P + 0.1 m <--- 0.1 m - 0.3 m 0.3 m 0.3 m |0.3 m 0.5 m 92 = -25 µC 92 = -25 µC Figure 1 Figure 2 q-90 μC
Two electric dipoles of dipole moment p, and p, are placed at origin such that one is along x-axis and the P2 3 òther along y-axis respectively. If potential at point (r,0) is zero then P2 is (а) 1 (b) cot0 (c) tan 0 (d) sin0.cos0
Consider a point charge and an arbitrary field point P in space. The electric potential due to the point charge at position P varies •inversely with the square of the distance between the point charge and field point P •inversely with the distance between the point charge and field point P •directly with the square of the distance between the point charge and field point P •directly with the distance between the point charge and field point P •none of the given choices
33. ssm The inner and outer surfaces of a cell membrane carry a negative and a positive charge, respectively. Because of these charges, a potential difference of about 0.070 V exists across the membrane. The thickness of the cell membrane is 8.0 × 10-⁹ m. What is the magni- tude of the electric field in the membrane?
A spherical conductor has a radius of 14.0 cm and a charge of 80.0 µC. Calculate the electric field and the electric potential at the following distances from the center. (а) r %3D 6.0 сm magnitude direction electric field MN/C ---Select--- electric potential| MV ---Select--- (b) r = 22.0 cm magnitude direction electric field MN/C ---Select--- electric potential MV ---Select--- (c) r = 14.0 cm magnitude direction electric field MN/C ---Select--- electric potential MV ---Select--- Need Help? Master It
S-1) Find the potential difference A (2, 1 / 2, 0) and B (4, 11, 5) VAB for a linear charge with density pl = 0.5 nC/m on the z-axis
3) Point charges q, L = 2 m has a total charge q =100 µC and a uniform linear charge density 2 = 50 µC/m in Figure 2. (a) Find the potential at P in Figure 1. (b) Find the total potential energy of charge system in Figure 1. (c) Find the total potential at P in Figure 2. (k = 9×109 N×m²/C², and µ= 10-6) 30 μC, q--20 μC , and q 10 µC are located in Figure 1. A rod with length λ-50 μC/m Qι-30 μC 91 = 30 μC 1 + L = 2 m %3D 0.3 m 0.5 m 4-10 μC 0.3 m + 0.2 m - 0.2 m --> 0.2 m 0.2 m 0.3 m 0.3 m ´0.5 m 92 = -20 µC q2 = -20 µC -1 Figure 1 Figure 2 q- 100 μC
2Q 3R²r The charge density of an insulating sphere of radius R is given as p(r) insulation sphere is placed at the center of a conducting spherical shell of inner Radius of 2R and outer radius 3R which has the total charge of +20. = Which of the followings is the potential difference between the points A a) o b) k 20 R c) k 2Q 5R d) k 2R e) k 5R +2Q 3R R2R (p(r) = Conductor The 5 R and TB = R?