The sketech below show cross secion so equipotential surfaces between two charged.Conductors that are shwon in solid black.Some points on the wquipotenital surfaces .near the conductors are marked as `A,B,C…. .` The arrangements lies in air (Take `epsilon_(0)=8.85xx10^(-12)C^(2)//Nm^(2)]`

A positive charge is placed at `B`,When it is released:

The sketch below show cross section so equipotential surfaces between two charged.Conductors that are shown in solid black.Some points on the equipotenital surfaces .near the conductors are marked as A,B,C…. . The arrangements lies in air (Take epsilon_(0)=8.85xx10^(-12)C^(2)//Nm^(2)] Surfaces charge density of the plate is equal to

The surface density of charge on the surface of a charged conductor in the air is 26.5 muCm^(-2) . The the outward force per unit area of the charged conductor is (epsilon_0=8.85xx10^-12C^2N^-1m^-2)

An infinite nonconducting sheet of charge has a surface charge density of 10^(7) C//m^(2) . The separation between two equipotential surfaces near the whose potential differ by 5V is

A parallel plate capicitaor with plates of area 1m^2 each, are at a separation of 0.1 m. If the electric field between the plates is 100 N//C , the magnitude of charge on each plate is : (Take epsilon=8.85xx10^-12(C^2)/(N-m^2) )

Two charges of 4 mu C each are placed at the corners A and B of an equilaternal triangle of side length 0.2 m in air. The electric potential at C is [(1)/(4pi epsilon_(0)) = 9 xx 10^(9) (N-m^(2))/(C^(2))]

In the rectangle, shown below, the twp corners have charges q_(1)=-5muC and q_(2)=+ 2.0 muC . The work done in moving a charge +3.0 muC from B to A is (take 1//4 pi epsilon_(0)=10^(10)"N-m"^(2)//C^(2) )

Two parallel large thin metal sheets have equal surface charge densities (sigma = 26.4 xx 10^(-12) C//m^(2)) of opposite signs. The electric field between these sheets is

Each plate of a parallel plate air capacitor has area S=5xx10^(-3) m^(2) and the distance between the plates is d=8.80 mm .Plate A has positive charge q_(1)=+10^(-10) C , and plate B has charge q_(2)=+2xx10^(-10) C . A battery of emf E=10 V has its positive terminal connected to plate A and the negative terminal to plate B. (Given epsilon_(0)=8.8xx^(12) Nm^(2) C^(-2)) . Charge supplied by time the battery is .

Each plate of a parallel plate air capacitor has area S=5xx10^(-3) m^(2) and the distance between the plates is d=8.80 mm . Plate A has positive charge q_(1)= +10^(-10) C , and plate B has charge q_(2)=+2xx10^(-10) C . A battery of emf E=10 V has its positive terminal connected to plate A and the negative terminal to plate B . (Given epsilon_(0)=8.8xx10^(-12) Nm^(2) C^(-2)) . Energy supplied by the battery is.

Find the flux of the electric field through a spherical surface of radius R due to a charge of 8.85xx10^(-8) C at the centre and another equal charge at a point 3R away from the centre (Given : epsi_(0) = 8.85 xx 10^(-12) units )