Statement (A) : Ampere's law states that the line integral of `vecB.vecdl` along a closed path round the current carrying conductor is equal to `μ_(0)i` (i is the net current through the surface bounded by the closed path)
Statement (B) : Ampere's law can be derived from Biot savart's law

A current of 1//(4pi) ampere is flowing in a long straight conductor. The line integral of magnetic induction around a closed path enclosing the current carrying conductor is

A conductor carries a constant current I along the closed path abcdefgha involving 8 of the 12 edges of length l . Find the magnetic dipole moment of the closed path.

A conductor carries a constant current I along the closed path abcdefgha involving S of the 12 edges each of length 1. Find the magnetic dipole moment of the closed path.

the below figure shown two closed paths wrapped around two conducting loops carrying currents i_(1)-5.0 A and i_(2) = 3.0 A . Whar is the value of the integal ointvecB.dvecs for (a) path a 1and d(b) path (2) ?

(A) : The magnetic field at the centre of a circular coil carrying current could be calculated using Amperes law. (R) : Biot savart law could be derived from Amperes law.

Using Ampere 's circuital law or Biot- Savart's a law, show that magnetic flux density B at point P at a perpendicular distance a from a long current carrying conductor is given by B=(mu/(4 pi))(2I)/(a) [ Statement of the laws not required]

(a) Using Ampere.s circuital law or Biot Savart.s law, show that magnetic flux density .B. at a point P at a perpendicular distance.d from a long current carrying conductor is given by: B=(mu_0/(4pi)) (2I)/a (Statement of the law is not required) (b) Define the terms (i) drift velocity, (ii) relaxation time. A conductor of length L is connected to a d.c. source of emf E. If this conductor is replaced by another conductor of same material and same area of cross-section but of length 3L, how will the drift velocity change?

Statement I: no electric current will be present within a region having uniform and constant magetic field. Statement II: Within a region of unifrom and cinstant magnetic field vec(B) , the path integral of magnetic field oint vec(B).dvec(l) along any closed path is zero. Hence, from Ampere cirauital law oint vec(B).dvec(l) = mu_(0)I (where the given terms ahve usual meaning), no current can be present within a region having uniform and constant magnetic field .

Ampere's law provides us an easy way to calculate the magnetic field due to a symmetrical distribution of current. Its mathemfield expression is ointvecB.dl=mu_0I_("in") . The quantity on the left hand side is known as line as integral of magnetic field over a closed Ampere's loop. If the current density in a linear conductor of radius a varies with r according to relation J=kr^2 , where k is a constant and r is the distance of a point from the axis of conductor, find the magnetic field induction at a point distance r from the axis when rlta. Assume relative permeability of the conductor to be unity.

A metal bar AB can slide on two parallel thick metallic rails separated by a distance l. A resistance R and an inductance L are connected to the rails as shown in the figure. A long straight wire carrying a constant current I_(0) is placed in the plane of the rails and perpendicular to them as shown. The bar AB is held at rest at a distance x_(0) from the long wire. At t=0, it is made to slide on the rails away from wire. Answer the following questions. (a) Find a relation among i, (di)/(dt) and (d phi)/(dt) , where i is the current in the circuit and phi is the flux of the megnetic field due to the long wire through the circuit. (b) It is observed that at time t=T, the metal bar AB si at a distance of 2x_(0) from the long wire and the resistance R carries a current (i_1) . Obtain an expression for the net charge that has flown through riesistance R form t=0 to t=T. (c) THe bar is suddenly stopped at time T. THe current through resistance R is found to be (i_1)/(4) at time 2T. Find the value of L/R in terms of hte other given quantities.