Figure shows a square loop carrying current I is present in the magnetic field which is given by `vecB=(B_(0)z)/(L)hatj+(B_(0)y)/(L)hatk` where `B_(0)` is positive constant. Which of the following statement(s) is/are correct?

Given a+b+c+d=0 . Which of the following statements(s) is (are) correct?

A square of side x m lies in the x-y plane in a region, when the magntic field is given by vecB=B_(0)(3hati+4hatj+5hatk) T, where B_(0) is constant. The magnitude of flux passing through the square is

A circular loop of radius R carrying current I is kept in XZ plane. A uniform and constant magnetic field vecB=(B_(0)hati+2B_(0)hatj+3B_(0)hatk) exists in the region ( B_(0)- a positive constant). Then the magnitude of the torque acting on the loop will be

The figure shows a loop of wire carrying a current i as shown. There exists a uniform magnetic field along x-axis given by vec(B) = B_(0) hat(i) . If the length of each side is a, then

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

A positive charge particle to charge q& mass m is released at origin.There are unifrom magnetic and electric field in the space given by vecE=E_(0)hatj & vecB = B_(0)hatk , where E_(0) & B_(0) are constants.Find the y coordinate of the particle at time t .

When current (I) in R-L series circuit becomes constant, where L is a pure inductor, which of the following given statements is/are correct?

A square loop EFGH of side a, mass m and total resistance R is falling under gravity in a region of transverse non - uniform magnetic field given by B=B_(0)^(y)/(a) =, where B_(0) is a positive constant and y is the position of side EF of the loop. If at some instant the speed of the loop is v, then the total Lorentz acting on the loop is