Two particle, each having a mass `m` are placed at a separation `d` in a uniform magnetic field `B` as shown in figure.They have opposite charges of equal magnitude `q`.At time `t=0`, the particles are projected towards each other, each with a speed `v`.
What would be the minimum separation between the particles if `v=v_(m)/4`?

Two particle, each having a mass m are placed at a separation d in a uniform magnetic field B as shown in figure.They have opposite charges of equal magnitude q .At time t=0 , the particles are projected towards each other, each with a speed v . What would be the maximum separation between the particles if v=v_(m)/4 ?

Two particle, each having a mass m are placed at a separation d in a uniform magnetic field B as shown in figure.They have opposite charges of equal magnitude q .At time t=0 , the particles are projected towards each other, each with a speed v . At what instant will a collision occur between the particles if v=2v_(m) ?

Two particle, each having a mass m are placed at a separation d in a uniform magnetic field B as shown in figure.They have opposite charges of equal magnitude q .At time t=0 , the particles are projected towards each other, each with a speed v . Suppose v=2v_(m) and they stick to each other after the collision.Describe the motion after the collision (neglect the magnetic, gravitational & electric forces between charges).

Two particles, each having a mass m are placed at a separation d in a uniform magnetic field B as shown in they have opposite charges of equal magnitude q. at time t =0, the particles are projectd towards each other,each with a speed v. suppose the coulomb force between the charges is switched off. (a) Find the maximum value v_m of the projection speed so that the two particles do not collide. (b) What would be the minimum and maximum separation between the particles if v = v_m /2? (c) At what instant will a collision occur between the particles if v = 2v_m ? (d) Suppose v =2v_m and the collision between the particles is completely inelastic. Describe the motion after the collision.

A charge particle of mass m and charge q enters in a region of uniform magnetic field as shown in figure.The magnitude of change in linear momentum due to magnetic field will be

A long , straight wire carries a current i. A particle having a positive charge q and mass m, kept at a distance x_0 from the wire is projected towards it with a speed v. Find the minimum separation between the wire and the particle.

A charge particle q of mass is placed at a distance d from another charge particle -2q of mass 2 m in a uniform magnetic field B as shown if particle are projected towareds each other with equal speed v_(0) , so that the two particle touches each other without collision during its motion (Assume only force due to magnetic field acts on the particle)

In the figure shown a positively charged particle of charge q and mass m enters into a uniform magnetic field of strength B as shown in the figure.The magnetic field points inwards and is present only within a region of width d .The initial velocity of the particle is perpendicular to the magnetic field and phi=30^(@) .Find the time spent by the particle inside the magnetic field if d=0.2 m,B=1T,q=1C,m=1kg and v=1m//s .Use sin 45^(@)=0.7 if required .

A uniform magnetic field barB =B_(0)hatj exists in a space. A particle of mass m and charge q is projected towards negative x-axis with speed v from the a point (d,0,0) The maximum value v for which the particle does not hit y-z plane is .

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.