4) (a)Using the Gauss law find the electric field of an infinite conductor planewith charge density σ.(b)Using the result in part (a) calculate the capacitance of a capacitor made oftwo conducting plane of 2 m2 area and with charge density σ = 9.6 C/m 2 andthese conducting planes are separated with a distance 0.1 mm and there isAluminium oxide as the dielectric between two plates.*Take gravitational constant g =10 m/s2. 4) (a)Using the Gauss law find the electric field of an infinite conductor planewith charge density o.(b)Using the result in part (a) calculate the capacitance of a capacitor made oftwo conducting plane of 2 m2 area and with charge density o = 9.6 C/m2 andthese conducting planes are separated with a distance 0.1 mm and there isAluminium oxide as the dielectric between two plates.

4) (a)Using the Gauss law find the electric field of an infinite conductor plane with charge density o. (b)Using the result in part (a) calculate the capacitance of a capacitor made of two conducting plane of 2 m² area and with charge density o = 9.6 C/m² and these conducting planes are separated with a distance 0.1 mm and there is Aluminium oxide as the dielectric between two plates.

4) (a)Using the Gauss law find the electric field of an infinite conductor plane with charge density o. (b)Using the result in part (a) calculate the capacitance of a capacitor made of two conducting plane of 2 m² area and with charge density o = 9.6 C/m² and these conducting planes are separated with a distance 0.1 mm and there is Aluminium oxide as the dielectric between two plates.

University Physics Volume 2

18th Edition

ISBN:9781938168161

Author:OpenStax

Publisher:OpenStax

Chapter8: Capacitance

Section: Chapter Questions

Problem 70AP: A parallel-plate capacitor with capacitance 5.0F is charged with a 12.0-V battery, after which the...

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