Three equal charges are placed at the three corners of an isoscles triangle as shown in the figure. The statement which is true for electric potential `V` and the field intensity `E` at the centre of the triangle-

Three eqal charges +Q each are at the corners of an equilibrium triangle as shown. The intensity of electric field at O will be

If three point charges are placed at the three corners of a square of diagonals 2a as shown in figure. Then int_(B)^(A) vecE.vec(dr) will be -

Three charges +q , +q, and Q are placed at the comers of a right angled isosceles triangle as shown in the figure. If the net potential energy of the system is zero then value of Q is

Three charges Q_(0) , - q and -q are placed at the vertices of an isosceles right angle triangle as in the figure. The net electrostatic potential energy is zero if Q 0 is equal to :

Three charges are arranged on the vertices of an equilateral triangle as shown in figure (29.E6) find the dipole moment of the combination.

Three equal masses m are placed at the three corners of an equilateral triangle of side a. find the force exerted by this system on another particle of mass m placed at (a) the mid point of a side (b) at the center of the triangle.

Four charges are arranged at the corners of a square as shown in the figure. The direction of electric field at the centre of the square is along

Equal charges q are placed at the vertices A and B of an equilatral triangle ABC of side a . The magnitude of electric field at the point C is

Two north poles each of pole strength m and a south pole of pole strength m are placed at the three corners of an equilateral triangle of side a. The intensity of magnetic induction field strength at the centre of the triangle is

Three dipoles each of dipole moment of magnitude p are placed tangentially on a circle of radius R in its plae positioned at equal angle from each other as shown in the figure. Then the magnitude of electric field intensity at the centre of the circle will be :