b, q = 18X106 CConsider two hollow conducting spheres. Inner radius of the first sphere, a=4.0 m and outerradius, b=16.0 m. Inner radius of the second sphere, c=24 m and outer radius, d= 40 m.a. Calculate the net enclosed charge by the Gaussian surface of radius r=20m.b. Electric field at r=20m.c. Net flux through Gaussian sphere of r=20m.Calculate the potential at the following distances from the point charge q and explain yourresult. Assume that at infinity the potential is zero.d. Potential at r=d.e. Potential at r=c.f. Potential at r= (c+d)/2f) Plot electric field as a function of distance from origin for this system.g) (bonus) Plot electric potential as a function of distance from origin for this system.

Given data: q=18×106 C Net radius of inner sphere = r = (4+16)/2 = 10 m R = 20 m (a) Charge…

q = 18X106 C Consider two hollow conducting spheres. Inner radius of the first sphere, a=4.0 m and outer radius, b=16.0 m. Inner radius of the second sphere, c=24 m and outer radius, d= 40 m. a. Calculate the net enclosed charge by the Gaussian surface of radius r=20m. b. Electric field at r=20m. c. Net flux through Gaussian sphere of r=20m.

q = 18X106 C Consider two hollow conducting spheres. Inner radius of the first sphere, a=4.0 m and outer radius, b=16.0 m. Inner radius of the second sphere, c=24 m and outer radius, d= 40 m. a. Calculate the net enclosed charge by the Gaussian surface of radius r=20m. b. Electric field at r=20m. c. Net flux through Gaussian sphere of r=20m.

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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