A hemisphere (radius R) is placed in electric field as shown in fig. Total outgoing flux is -

Find out the flux through the curved surface of a hemisphere of radius R if it is placed in a uniform electric field E as shown in figure

Net electric flux through a sphere of radius 1 m placed in a uniform electric field as shown in the figure is → E = 103 N/C

A hemispherical bowl of radius r is placed in uniform electric field E . The electric flux passing through the bowl is

A hemispherical body of radius R is placed in a uniform electric field E. What is the flux linked with the curved surface if, the field is (a) parallel to the base, (b) perpendicular to the base.

A hemispherical body of radius R is placed in a uniform electric field E. If the field E is parallel to the base of the hemisphere the flux linked with it is

A conic surface is placed in a uniform electric field E as shown in figure. Such that the field is perpendicular to the surface on the side AB. The base of the cone is of radius R, and the height of the cone is h. The angle of the cone is theta . Find the magnitude of the flux that enters the cone's curved surface from the left side. Do not count the outgoing flux (thetalt45^@) .

A hemispherical body is placed in a uniform electric field E. What is the flux linked with the curved surface if the field is (a) parallel to base of the body , (b) perpendicular to base of the body and (c) perpendicular to the curved surface at every points as in figure.

A cone lies in a uniform electric field E as shown in figure. The electric flux entering the cone is

The electric flux through a hemispherical surface of radius R placed in a uniform electric field E parallel to the axis of the circular plane is

If a hemispherical body is placed in a uniform electric field E then the flux linked with the curved surface is E B