Explanation Figure 1 represents the a sphere of radius 2 a of non- conducting material having a uniform volume charge density ρ . The sphere has a spherical cavity of radius of a . Write the expression for electric field due to sphere of positive charge of radius 2 a using gauss law. 4 3 ( π r 3 ρ ε 0 ) = 4 π r 2 E + (I) Here, E + is the electric field, ρ is the volume charge density, r is the radius of the Gaussian surface and ε 0 is the free space of permittivity. Rearrange equation (I). E → + = ρ r 3 ε 0 r ^ = ρ r → 3 ε 0 (II) Write the expression for electric field due to sphere of negative charge of radius a within the cavity using gauss law. E → - = ρ r 1 3 ε 0 ( − r ^ 1 ) = − ρ 3 ε 0 r → 1 (III) From Figure 1 r → is given by r → = a → + r → 1 from vector law of addition. Apply the above condition in equation (III)

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN: 9781133104261

Author: Raymond A. Serway, John W. Jewett

Publisher: Cengage Learning

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Chapter 19, Problem 78P

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To show that the electric field inside the cavity along x direction is Ex=0_, along y direction is Ey=ρa3ε0_.

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Chapter 19, Problem 77P

Chapter 20.1, Problem 20.1QQ

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Principles of Physics: A Calculus-Based Text

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To show that the electric field inside the cavity along x direction is E x = 0 _ , along y direction is E y = ρ a 3 ε 0 _ .

Solution Summary: The author illustrates the electric field inside the cavity along x direction, and the free space of permittivity using gauss law.

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To show that the electric field inside the cavity along x direction is Ex=0_, along y direction is Ey=ρa3ε0_.

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Chapter 19 Solutions