Four charges equal to -Q are placed at the four corners of a square and a charge q is at its centre. If the system is in equilibrium, the value of q is
A charge +q is placed at the origin O of x-y axes as shown in the figure. The work done in taking a charge Q from A to B along the straight line AB is
In a region, the intensity of an electric field is given by E = 2i + 3j+ k in Nc-1. The electric flux through a surface S = 1Oi m2 in the region is
5 Nm2C-1
10 Nm2C-1
15 Nm2C-1
20 Nm2C-1
Two infinite parallel metal planes, contain electric charges with charge densities +σ and -σ respectively and they are separated by a small distance in air. If the permittivity of air is ε0,then the magnitude of the field between the two planes with its direction will be
σ/ε0 towards the positively charged plane
σ/ε0 towards the negatively charged plane
σ/(2ε0) towards the positively charged plane
0 and towards any direction
Two pith balls carrying equal charges are suspended from a common point by strings of equal length, the equilibrium separation between them is r. Now the strings are rigidly clamped at half the height. The equilibrium separation between the balls now become
An infinite sheet carrying a uniform surface charge density σ lies on the xy-plane. The work done to carry a charge q from the point to the point (where a is a constant with the dimension of length and ε0 is the permittivity of free space) is
Consider two concentric spherical metal shells of radii r1 and r2 (r2 > r1). If the outer shell has a charge q and the inner one is grounded, the charge on the inner shell is
zero
- q
The line AA' is on charged infinite conducting plane which is perpendicular to the plane of the of the paper. The plane has a surface density of charge σ and B is ball of mass m with a like charge of magnitude q. B is connected by string from a point on the line AA'. The tangent of angle (θ) formed between the line AA' and the string is
A hollow sphere of external radius R and thickness (t << R) is made of a metal of density ρ. The sphere will float in water, if
A charge q is placed at one corner of a cube. The electric flux through any of the three faces adjacent to the charge is zero. The flux through any one of the other three faces is
q/3ε0
q/6ε0
q/12ε0
q/24ε0
D.
q/24ε0
Consider the diagram
In above the flux coverage of three face is shown in figure which is like a quadrant in any plane. So, flux will be