Hello, sorry for the inconvenience but can you please answer the following three questions? Thanks in advance 1. The linear charge density of an infinite line charge is 0.3 10 .m C --16 x Assumingthat the electric potential at a perpendicular distance of 5.0 m from the wire is zero,calculate the potential at the perpendicular distance of 6.0 m.2. The radius and surface charge density of a uniformly charged spherical shell are20 cm and ,m C0.3–2 µ respectively. Calculate the electric potential at a distance(a) 40 cm and (b) 15 cm from the center of the shell.3. An isolated solid sphere of aluminum having radius 7.0 cm is at a potential of 500V. Calculate the number of electrons which have been removed from the sphereto raise it to this potential.

Part (1) Given: Linear charge density is λ=0.31×10-16 mC/m=0.31×10-19 C/m Perpendicular distances…

1. The linear charge density of an infinite line charge is 0.3 10 .m C --16 x Assuming that the electric potential at a perpendicular distance of 5.0 m from the wire is zero, calculate the potential at the perpendicular distance of 6.0 m.

1. The linear charge density of an infinite line charge is 0.3 10 .m C --16 x Assuming that the electric potential at a perpendicular distance of 5.0 m from the wire is zero, calculate the potential at the perpendicular distance of 6.0 m.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter16: Electrical Energy And Capacitance

Section: Chapter Questions

Problem 11P: An electron is at the origin, (a) Calculate the electric potential VA at point A, x = 0.250 cm. (b)...

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Hello, sorry for the inconvenience but can you please answer the following three questions? Thanks in advance

1. The linear charge density of an infinite line charge is 0.3 10 .m C --16 x Assuming
that the electric potential at a perpendicular distance of 5.0 m from the wire is zero,
calculate the potential at the perpendicular distance of 6.0 m.
2. The radius and surface charge density of a uniformly charged spherical shell are
20 cm and ,m C0.3–2 µ respectively. Calculate the electric potential at a distance
(a) 40 cm and (b) 15 cm from the center of the shell.
3. An isolated solid sphere of aluminum having radius 7.0 cm is at a potential of 500
V. Calculate the number of electrons which have been removed from the sphere
to raise it to this potential.

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