A loop made of straight edegs has six corners at `A(0,0,0), B(L, O,0) C(L,L,0), D(0,L,0) E(0,L,L)` and `F(0,0,L)`. Where `L` is in meter. A magnetic field `B = B_(0)(hat(i) + hat(k))T` is present in the region. The flux passing through the loop `ABCDEFA` (in that order) is

A loop A(0,0,0)B(5,0,0)C(5,5,0)D(0,5,0)E(0,5,10) and F(0,0,10) of straight edges has six corner points and two sides. The magnetic field in this region is vec(B) = (3hati + 4hatk) T. The quantity of flux through the loop ABCDEFA (in Wb) is

L_(1)=L_(0)+rt . What does L_(0) represent in the given expression?

Consider a loop ABCDEFA. With coordinates A (0, 0, 0), B(5, 0, 0), C(5, 5, 0), D(0, 5, 0) E(0, 5, 5) and F(0, 0, 5). Find magnetic flux through loop due to magnetic field vecB = 3 hati+4 hatk

A loop ABCA of straight edges has three corner points A (8, 0, 0), B (0, 8, 0 ) and C (0, 0, 8). The magnetic field in this region is vecB=5(hati+hatj+hatk)T 0 . The quantity of flux through the loop ABCA (in Wb) is _____.

A square shaped, conducting wire loop of side L , total mass m and total resistance R initially lies in the horizontal x-y plane, with corners at (x, y, z) = (0,0,0), (0, L , 0), (L, 0 ,0), and (L, L, 0) . There is a uniform upward magnetic field in the space within and around the loop. The side of the loop that extends from (0, 0, 0)to (L, 0, 0) is held in place on the x-axis, the rest of the loop is released, it begins to rotate due to the gravitational torque. (a) Find the net torque (magnitude and direction)that acts on the loop when it has rotated through an anglr phi from its original orientation and is rotating dounward at an angular speed omega . (b) Find the angular acceleration of the loop at the instant described in part (a). ( c) Compared to teh case with zero magnetic field, does it take the loop a longer or shorter time to rotate through 90^(@) ? Explain. (d) Is mechanical energy conserved as the loop rotates downward ? Explain.

A square of side L meters lies in the x-y plane in a region, where the magnetic field is give by B = B_(0) (2 hati + 3 hat j + 4 hatk) T, where B_(0) is constant. The magnitude of flux passing through the square is