A uniform magnetic field exists in the space `vecB=B_(1)hati+B_(2)hatj+B_(3)hatk`. Find the magnetic flux through an area `vecS` if the area `vecS` is in (i) x-y plane (ii) y-z plane (iii) z-x plane

A uniform magnetic field exists in the space B=B_(1)hati+B_(2)hatj-B_(3)hatk . Find the magnetic flux through an area S, if the area S is in yz - plane.

If an electric field is given by 10hati+3hatj+4hatk calculate the electric flux through a surface of area 10 units lying in yz plane

The magnetic flux linked with a vector area vec(A) in a uniform magnetic field vec(B) is

The electric field in a region is given by E=ahati+bhatj . Hence as and b are constants. Find the net flux passing through a square area of side I parallel to y-z plane.

The electric field in a region is given by E=ahati+bhatj . Hence as and b are constants. Find the net flux passing through a square area of side I parallel to y-z plane.

A uniform electric field of magnitude E= 100 N C^(-1) exists in the space in x-direction. Calculate the flux of this field through a plane square of edga 10 cm placed in the y-z plane. Take the normal along the positive x-axis to be positive.

In a region of space, a uniform magnetic field B exists in the x-direction. An electron is fired from the origin with its initial velocity u making an angle alpha with the y direction in the y-z plane. In the subsequent motion of the electron,

A circular loop of radius R carrying current I is kept in XZ plane. A uniform and constant magnetic field vecB=(B_(0)hati+2B_(0)hatj+3B_(0)hatk) exists in the region ( B_(0)- a positive constant). Then the magnitude of the torque acting on the loop will be

The electric field in a region of space is given by E=5hati+2hatjN//C . The flux of E due ot this field through an area 1m^2 lying in the y-z plane, in SI units is

Electric field in a region is uniform and is given by vec(E)-a hati+b hatj+c hatk . Electric flux associated with a surface of area vec(A)=pi R^(2)hati is