A magnetic field `B=B_(0)hatj` exists in the region `a lt x lt 2a` and `B=-B_(0)hatj`, in the region `2a lt x lt 3a`, where `B_(0)` is a positive constant. A positive point charge moving with as velocity `v=v_(0)hati`, where `v_(0)` is a positive constant, enters the magnetic field at `x=a`, the trajectory of the charge in this region can be like:

A magnetic field vec(B) = B_(0)hat(j) , exists in the region a ltxlt2a , and vec(B) = -B_(0) hat(j) , in the region 2a lt xlt 3a , where B_(0) is a positive constant . A positive point charge moving with a velocity vec(v) = v_(0) hat (i) , where v_(0) is a positive constant , enters the magnetic field at x= a . The trajectory of the charge in this region can be like

A particle having charge q moves with a velocity v through a region in which both an electric field vecE and a magnetic field B are present. The force on the particle is

An electron is moving with an initial velocity vecv=v_(0)hati and is in a magnetic field vecB=B_(0)hatj . Then it's de-Broglie wavelength

An electron is moving with an initial velocity vecv=v_(0)hati and is in a magnetic field vecB=B_(0)hatj . Then it's de-Broglie wavelength

Magnetic field exist in the space and given as vecB=-(B_(0))/(l^(2))x^(2)hatk , where B_(0) and l positive constants. A particle having positive charge 'q' and mass 'm' is pojected wit speed 'v_(0)' along positive x axis from the origin. What is the maimum distance of the charged particle from the y -axis before it turns back due to the magnetic field. (Ignore any interaction other than magnetic field)

A magnetic field vec(B)=-B_(0)hat(i) exists within a sphere of radius R=v_(0)Tsqrt(3) where T is the time period of one revolution of a charged particle starting its motion form origin and moving with a velocity vce(v)_(0) = (v_0)/(2) sqrt(3) hat(i) - v_(0)/(2) hat(j) . Find the number of turns that the particle will take to come out of the magnetic field.

A particle of mass m and charge Q moving with a velocity v enters a region on uniform field of induction B Then its path in the region is s

In region x gt 0 a uniform and constant magnetic field vec(B)_(1) = 2 B_(0) hat(k) exists. Another uniform and constant magnetic field vec(B)_(2) = B_(0) hat(k) exists in region x lt 0 A positively charged particle of mass m and charge q is crossing origin at time t =0 with a velocity bar(u) = u_(0) hat(i) . The particle comes back to its initial position after a time : ( B_(0),u_(0) are positive constants)

A particle of mass m and having a positive charge q is projected from origin with speed v_(0) along the positive X-axis in a magnetic field B = -B_(0)hatK , where B_(0) is a positive constant. If the particle passes through (0,y,0), then y is equal to

A particle of specific charge alpha is projected from origin with velocity v=v_0hati-v_0hatk in a uniform magnetic field B=-B_0hatk . Find time dependence of velocity and position of the particle.