Electric field in a region of space is given by `vec E=ayhat i+axhat j` then

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

The electric field in a region of space is given as bar(E)=(5xhat i-2hat j) .Potential at point x =1 y =1 is V_(1) and potential at point x =2 y =3 is V_(2) .Then V_(1)-V_(2) is equal to

The electric field in a region of space is given as bar(E)=(5xhat i-2hat j) .Potential at point x=1 y=1 is V_(1) and potential at point (x=2 y=3) is V_(2) .Then V_(1) -V_(2) is equal to

Electric field function in a region of space is given as → E = y i + x j. The shape of equipotential surface is

The electric field in a region of space is given bar(E)=E_(0)hat i+2E_(0)hat j where E_(0)=100N/C .The flux of this field through a circular surface of radius 0.02m parallel to the Y-Z plane is nearly:

The electric field in a region of space is given by E = (5 hat(i) + 2hat(j))N//C . The electric flux due to this field through an area 2m^(2) lying in the YZ plane, in S.I. unit 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

The electric field in a region of space is given by, E=5veci+2vecj N//C The electric flux through an area 2m^(2) lying in the YZ plane in SI unit is

Electric field in a region is given by vec(E)=-4xhat(i)+6yhat(j) . The charge enclosed in the cube of side 1 m oriented as shown in the diagram is given by alpha in_(0) . Find the value of alpha .