An infinitely long uniform line charge distribution of charge per unit length `lambda` lies parallel to the y - axis in the y - plane at ` x = (sqrt(2))/(2)` a (see figure ). If the magnitude of the flux on the r electric `(lambda L)/( n epsi_(0))` ( `epsi_(0)` = permittivity of free space ), ten find the value of n is .

An infinity long uniform line charge distribution of charge per unit length lambda lies parallel to the y-axis in the y-z plane at z=sqrt3/2 a(see figure). If the magnitude of the flux of the electric field through the rectangular surface ABCD lying in the x-y plane with its centre at the origin is (lambdaL)/(nepsilon_0) ( epsilon_0= permittivity of free space), then the value of n is

An infinite line of charge lamda per unit length is placed along the y-axis. The work done in moving a charge q from A(a,0) to B (2a,0) is

An infinitely long string uniformly charged with a linear charge density lambda_(1) and a segment of length l uniformly charge with linear charge density lambda_(2) lie in a plane at right angles to each other and separated by a distance r_(0) as shown in figure. The force with which these two interact is (lambda_(1) lambda_(2))/(4 pi epsi_(0)) ln (x) . If l=r_(0) , then find the value of x.

A wire of length L= 20 cm is bent into a semicircular arc and the two equal halves of the arc are uniformly charged with charges +Q and -Q as shown in the figure. The magnitude of the charge on each half is |Q| =10^(3) epsilon_(0) , where epsilon_(0) is the permittivity of free the space. The net electric field at the center O is

Two infinitely long thin straight wires having uniform linear charge densities lambda and 2lambda are arranged parallel to each other at a distance r apart.The intensity of the electric field at a point midway between them is

A inifinite length current carrying wire is placed in x,y plane parallel to y axis as shown in figure. (All charges projected in region l)

Three infinite planes have a uniform surface charge distribution sigma on its surfaces. All charges are fixed. On each of the three infinite planes, parallel to the yz plane placed at x = -a, x =0, and x = a , there is a uniform surface charge of the same density, sigma . The potential difference between A and C is

An infinite thread of charge density lambda lies along z-axis. The potential difference between points A (4, 3, 4) and (3, 4, 0) is

A hollow sphere having uniform charge density rho (charge per unit volume) is shown in figure. If b = 2a and potential difference between A and B is (rhoa^(2))/(n epsi_(0)) . Then find the value of n :

Two charges of equal magnitude q are placed in air at a distance 2a apart and third charge -2q is placed at mid-point . The potential energy of the system is (epsi_(0) = permittivity of free space)