The net flux passing through a closed surface enclosing unit charge is

(A): A point charge is lying at the centre of a cube of each side. The electric flux emanating from each surface of the cube is (1^(th))/(6) total flux. (R ): According to Gauss theorem, total electric flux through a closed surface enclosing a charge is equal to 1//epsi_(0) times the magnitude of the charge enclosed.

A capacitor of capacitance C is charged to a potential V . The flux of the electric field through a closed surface enclosing the capacitor is

A capacitor of capacitance C is connected to a cell of emf V and when fully charged, it is disconnected. Now the separation between the plates is doubled. The change in flux of electric field through a closed surface enclosing the capacitor is

Assertion : Total flux through a closed surface is zero if no charge is enclosed by the surface. Reason : Gauss law is true for any closed surface, no matter what its shape or size is.

The total electric flux emanating from a closed surface enclosing an alpha particale (e = electronic chage) is

Charge is distributed uniformly in some space. The net flux passing through the surface of an imaginary cube of side a in the space is phi . The net flux passing through the surface of an imaginary sphere of radius a in the space will be

Statement-1 The net magnetic flux through a spherical surface enclosing north pole of a bar magnet as zero Statement-2 Magnetic field lines always form closed loops

Statement-1 The net magnetic flux through a spherical surface enclosing north pole of a bar magnet as zero Statement-2 Magnetic field lines always form closed loops

Statement-1 The net magnetic flux through a spherical surface enclosing north pole of a bar magnet as zero Statement-2 Magnetic field lines always form closed loops

A uniformly charged conducting sphere is having radius 1 m and surface charge density 20" Cm"^(-2) . The total flux leaving the Gaussian surface enclosing the sphere is