The region between x=0 and x=L is filled with uniform constant magnetic field 25(T)`hatk`. A particle of mass m=50g having positive charge q=1C and velocity `vecV_0=50sqrt3hati+50hatjms^-1` enters the region of the magnetic field. Neglect gravity throughout the question.

The value of L if the particle emerges from the region of magnetic field with its velocity `100(ms^-1)hati` is

The region between x=0 and x=L is filled with uniform constant magnetic field 25(T) hatk . A particle of mass m=50g having positive charge q=1C and velocity vecV_0=50sqrt3hati+50hatjms^-1 enters the region of the magnetic field. Neglect gravity throughout the question. The maximum and minimum values of L such that velocity of emerging particle makes angle pi//3 with the y-axis are

The region between x=0 and x=L is filled with uniform steady magnetic field B_0hatk . A particle of mass m, positive charge q and velocity v_0hati travels along x-axis and enters the region of the magnetic field. Neglect the gravity throughout the question. a. Find the value of l if the particle emerges from the region of magnetic field with its final velocilty at an angel 30^@ to its initial velocity. b. Find the final velocity of the particle and the time spent by it in the magnetic field, if themagnetic field now extends upto 2.1 L .

The region between x=o and x = L is filled with uniform, steady magnetic field B_(0) hat(k) . A particle of mass m , positive charge q and velocity v_(0) hat(i) travels along x-axis and enters the region of the magnetic field. Neglect gravity throughout the question . (a) Find the value of L if the particle emerges from the region of magnetic field with its final velocity at angle 30^(@) to its initial velocity. (b) Find the velocity of the particle and the time spent by it in the magnetic field, if the magnetic field now extends upto 2.1L .

A particle of mass m having a charge q enters into a circular region of radius R with velocity v directed towards the centre. The strength of magnetic field is B . Find the deviation in the path of the particle.

A positive charge particle having change q and mass m has velocity vecv = v((hati+hatk)/sqrt2) in the magnetic field B at the origin . Its speed as the function of y is :

The figure shows two regions of uniform magnetic field of strengths 2B and 2B. A charged particle of mass m and charge q enters the region of the magnetic field with a velocity upsilon = (q B w)/(m) , where w is the width of each region of the magnetic field. The time taken by the particle to come out of the region of the magnetic field is

The region between y =0 and y=d constains a magnetic field vecB = Bvecz . A particle of mass m and charge q enters of the region with a velocity vecv = v veci . If d =(mv)/(2qB) the acceleration of the charged particle at the point of its emergence at the other side is :

A particle of charge q and mass m moving with a velocity v along the x-axis enters the region xgt0 with uniform magnetic field B along the hatk direction. The particle will penetrate in this region in the x -direction upto a distance d equal to

A particle of the mass m and cgharge q moves with a constant velocity v along the positive x- direction . It enters a region containing a uniform magnetic field B directed along the minimum value of v required so that the particle can just enter the region xgtb is