A 1 `mu` C charge is uniformly distributed on a spherical shell given by the equation `x^(2)+y^(2)+z^(2)=25 `.
What will be the intensity of electric field at a point (1,1,2) ?

A 1mu C charge is uniformly distributed on a spherical shell given by the equation x^(2)+ y^(2) +z^(2) = 25 . What will be the intensity of electric field at a point ( 1,1,2) ?

A force of 2.25 N acts on a charge of 15xx10^(-4)C . The intensity of electric field at that point is

In a certain region of space, the potential is given by V=k(2x^(2)-y^(2)+z^(2)) . The electric field at the point (1, 1, 1) has magnitude:

A thin non-conducting hemispherical shell contains a positive charge q on it, which uniformly distributed on the shell. A point P lies on the diameter of shell as show in figure. Then the direction of electric field at the point 'P' is

A charge Q is uniformly distributed on a thin spherical shell. What is the field at the centre of the shell? If a point charge is brought close to the shell, will the field at the centre change? Does your answer depend on whether the shell is conducting or nonconducting?

The electric potential at a space point P (X, Y, Z) is given as V= x^(2)+y^(2)+z^(2) . The modulus of the electric field at that point is proportional to

A uniformly charged non-conducting spherical shell is given +q charge and a point charge -q is placed as shown. The electric field lines will be

The potential of the electric field produced by point charge at any point (x, y, z) is given by V = 3x^(2) + 5 , where x ,y are in are in metres and V is in volts. The intensity of the electric field at (-2,1,0) is :

A charge Q is uniformly distributed in a dielectric sphere of radius R (having dielectric constant unity). This dielectric sphere is enclosed by a concentric spherical shell of radius 2R and having uniformly distributed charge 2Q. Which of the following graph correctly represents variation of electric field with distance r from the common centre?

STATEMENT-1 : Electric field at a point due to an infinite sheet of uniformly distributed charge is independent of distance between the point from the sheet. STATEMENT-2 : Electric field at a pont due to an uniformly distributed long charged rod is inversity proportional to distance between the point and rod. STATEMENT-3 : Electric field at a point due to an electric dipole is inversely proportional to the cube of distance between point and centre of dipole.