A uniform magnetic field `B=(3hati+4hatj+hatk)` exists in region of space. A semicircular wire of radius 1 m carrying current 1A having its centre at (2, 2, 0) is placed in x-y plane as shown in the figure. The force on semicircular wire will be :

A uniform magnetic field vec(B) = 3 hat i + 4 hat j + hat k exists in region of space. A semicircular wire of radius of 1 m carrying current 1 A having its centre at (2, 2, 0) is placed in x-y plane as shown in Fig. The force on semicircular wire will be

Find the magnetic field B due to a semicircular wire of radius 10.0 cm carrying a current of 5.0A at its centre of curvature .

A semicircular wire of radius r , carrying a current I , is placed in a magnetic field of magnitude B . The force acting on it

A semicircule wire of radius R and carrying a current I si placed in the XY plane where the uniform magnetic field is B = B_(0) K . The force on the wire is

What is the force experienced by a semicircular wire of radius R when it is carrying a current l and is placed in a uniform magnetic field of induction B as shown in figure. ?

The figure shows a semi-circular wire of radius 10 cm in the xy plane carrying current 2 A. If the magnetic field in the region is 3.0 T(-k) then the magnetic force on the wire will be

A magnetic field vecB = (hati + 0.5 hatj + 0.25 hatk) T exists in a space. A wire of length vecl = (0.25 hati - 0.25 hatj) m carries a current of 1 A and is placed in the magnetic field region. Find the magnitude of magnetic force on the wire.

A very long current carrying wire is placed along z- axis having current of magnitude i_(1) towards negative z- axis. A semicircular wire of radius R and having current i_(2) is placed in x-y plane, such that line joining two end points of the semicircular wire passes through long wire as shown in figure. Nearest distance of semicircular wire from long wire is R. Net magnetic form on semicircular wire will be

the force on current carrying wire placed in uniform magnetic field B as shown in figure is

A uniform magnetic field vecB of magnitude 0.2 T exists in the plane of paper from left to right. A conducting wire, bent in an irregular manner, and carrying a current i , equal to 5A is placed in the plane of paper as shown in figure. Force acting on the wire (in Newton) is