A non-conducting ring of radius `0.5 m` carries a total charge `1.11xx10^(-10)C` distributed non-uniformly on its circumference producing an electric field E evergy where in space. The value of the integral `int_(t=oo)^(i=0)-vec(E).vec(d)l` (`l=0` being centre of the ring) in volt is:

A spherical conductor of radius 12 cm has a charge of 1.6 xx 10^(-7) C distributed uniformly on its surface. What is the electric field (a) inside the sphere (b) just outside the sphere (c) at a point 18 cm from the centre of the sphere?

A spherical conductor of radius 12 cm has a charge of 1.6 xx 10^(-7) C distributed uniformly on its surface . What is the electric field (a) inside the sphere (b) just outside the sphere. (c) at a point 18 cm from the centre of the sphere ?

A thin spherical shell of radius R has charge Q spread uniformly over its surface. Which of the following graphs most closely represents the electric field E(r) produced by the shell in the range 0lerltoo , where r is the distance from the centre of the shell?

A nonconducting ring of mass m and radius R, with charge per unit length lambda is shown in fig. It is then placed on a rough nonconducting horizontal plane. At time t=0, a uniform electric field vecE =E_(0)hati is switched on and the ring starts rolling without sliding. Determine the friction force (magnitude and direction ) acting on the ring.

A solid non conducting sphere of radius R has a non-uniform charge distribution of volume charge density, rho=rho_(0)r/R , where rho_(0) is a constant and r is the distance from the centre of the sphere. Show that : (i) the total charge on the sphere is Q=pirho_(0)R^(3) (ii) the electric field inside the sphere has a magnitude given by, E=(KQr^(2))/R^(4)

Charge Q is distributed uniformly over a non conducting sphere of radius R. Find the electric p-0tential at distance r from the centre of the sphere r (r lt R) . The electric field at a distance r from the centre of the sphere is given as (1)/(4pi epsilon_(0)). (Q)/(R^(3))hatr . Also find the potential at the centre of the sphere .

A long straight cable of length l is placed symmetrically along z - axis and has radius a(lt lt l) . The cable consists of a thin wire and a co-axial conducting tube. An alternating current thin wire and returns along the coaxial conducting tube. The induced electric field at a distance s from the wire inside the cable is vec(E )(s, t)=mu_(0)I_(0)v cos (2pi vt) ln ((s)/(a))hat(k) Integrate the displacement current density across the cross - section of the cable to find the total displacement current I^(d) .

A long straight cable of length l is placed symmetrically along z - axis and has radius a(lt lt l) . The cable consists of a thin wire and a co-axial conducting tube. An alternating current thin wire and returns along the coaxial conducting tube. The induced electric field at a distance s from the wire inside the cable is vec(E )(s, t)=mu_(0)I_(0)v cos (2pi vt) ln ((s)/(a))hat(k) Compare the conduction current I_(0) with the displacement current I_(0)^(d) .

A long straight cable of length l is placed symmetrically along z - axis and has radius a(lt lt l) . The cable consists of a thin wire and a co-axial conducting tube. An alternating current thin wire and returns along the coaxial conducting tube. The induced electric field at a distance s from the wire inside the cable is vec(E )(s, t)=mu_(0)I_(0)v cos (2pi vt) ln ((s)/(a))hat(k) Calculate the displacement current density inside the cable.

A ring of mass 'm' and radius 'r' carrying current i_(0) is lying in the X-Y plane with centre at origin. A uniform magnetic field of strength B=B_(0) (2hat(i)-3hatj+5hatk)T is applied in the region. If the ring rotates about the axis .initial magnetic energy stored in the ring will be. (In joules)