8. What is the electric flux density in free space ifthe electric field intensity is 1V/m?7.76 X 10^-12 C/ m^28.85 X 10^-12 C/ m^21.23 X 10^-12 C/ m^23.43 X 10^-12 C/ m^29. The diagram below shows some of the lines ofelectrical force around a positive point charge.Point A is nearest to the charge, point B is fartheraway, and point Cis the farthest. (second picture)greatest at point Agreatest at point Bgreatest at pointequal at points A,B, and C10. A solid conducting sphere is given a positivecharge Q. How is the charge Q distributed in or onthe sphere?It is concentrated at the center of the sphereIt is uniformly distributed throughout the sphere.Its density decreases radially outward from thecenter.It is uniformly distributed on the surface of thesphere only. AB

Given--- Electric field intensity ,E = 1 V/m Formula for electric flux density is given by ----- D…

8. What is the electric flux density in free space if the electric field intensity is 1V/m? 7.76 X 10^-12 C/m^2 8.85 X 10^-12 C/ m^2 1.23 X 10^-12 C/ m^2 3.43 X 10^-12 C/ m^2 9. The diagram below shows some of the lines of electrical force around a positive point charge. Point A is nearest to the charge, point B is farther away, and point Cis the farthest. (second picture) greatest at point A greatest at point B greatest at point C equal at points A,B, and C 10. A solid conducting sphere is given a positive charge Q. How is the charge Q distributed in or on the sphere? It is concentrated at the center of the sphere It is uniformly distributed throughout the sphere. Its density decreases radially outward from the center. It is uniformly distributed on the surface of the sphere only.

8. What is the electric flux density in free space if the electric field intensity is 1V/m? 7.76 X 10^-12 C/m^2 8.85 X 10^-12 C/ m^2 1.23 X 10^-12 C/ m^2 3.43 X 10^-12 C/ m^2 9. The diagram below shows some of the lines of electrical force around a positive point charge. Point A is nearest to the charge, point B is farther away, and point Cis the farthest. (second picture) greatest at point A greatest at point B greatest at point C equal at points A,B, and C 10. A solid conducting sphere is given a positive charge Q. How is the charge Q distributed in or on the sphere? It is concentrated at the center of the sphere It is uniformly distributed throughout the sphere. Its density decreases radially outward from the center. It is uniformly distributed on the surface of the sphere only.

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter24: Electric Fields

Section: Chapter Questions

Problem 56PQ

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Similar questions

(a) Using the symmetry of the arrangement, determine the direction of the electric field at the center of the square in Figure 18.53, given that qa= 1.00C and qc=qd= +1.00 C. (b) Calculate the magnitude of the electric field at the location of q, given that the square is 5.00 cm on a side.
Suppose the conducting spherical shell of Figure 15.29 carries a charge of 3.00 nC and that a charge of -2.00 nC is at the center of the sphere. If a = 2.00 m and b = 2.40 m. find the electric field at (a) r = 1.50 m, (b) r = 2.20 m, and (c) r = 2.50 m. (d) What is the charge distribution on the sphere?
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A very large nonconducting plate lying in the xy-plane carries a charge per unit area of . A second such plate located at z = 2.00 cm and oriented parallel to the xy-plane carries a charge per unit area of 2. Find the electric field (a) for z 0, (b) 0 z 2.00 cm, and (c) z 2.00 cm.