Non-relativistic protons move reactilinearly in the region of space where there are uniform mutually perpendicular electric and magnetic fields with E and B. The trajectory of the protons lie in the plane X-Y as shown in Fig. 1.107 and forms an angle `phi` with X-axis. Find the pitch of the helical trajectory along which the protons will move after the electric field is switched off.

Protons move rectilinearly in the region of space where there are uniform mutually perpendicular electric and magnetic fields E and B . The trajectory of protons lies in the plane xz as shown in the figure and forms an angle 9 with x-axis. Find the pitch of the helical trajectory along which the protons will move after the electric field is switched off.

A proton beam passes without deviation through a region of space where there are uniform transverse mutually perpendicular electric and magnetic field with E and B Then the beam strikes a grounded target. Find the force imparted by the beam on the target if the beam current is equal to I .

A non-relativistic proton beam passes without deviation through a region of space where there are uniform transverse mutually perpendicular electric and magnetic fields with E= 120 kVm^-1 and B=50 mT. Then the beam strikes a grounded target. Find the force which the beam acts on the target if the beam current is equal to i=0.8 mA . Mass of protons = 1.67xx10^(-27) kg .

A charged particle of specific charge s moves undeflected through a region of space containing mutually perpendicular and uniform electric and magnetic fields, E and B. When the field E is switched off, the particle will move in a circular path of radius

A charged particle of specific charge s moves undeflected through a region of space containing mutually perpendicular and uniform electric and magnetic fields, E and B. When the field E is switched off, the particle will move in a circular path of radius

A proton moves at a constant velocity of 50 m/s along the x-axis, in uniform electric and magnetic fields. The magnetic field is B = (2.0 mT)hatj . What is the electric field?

A uniform magnetic field B and electric field E exist along y and negative z axis respectively. Under the influence of these field a charge particle moves along OA undeflected. If electric field is switched off, find the pitch of helical trajectory in which the particle will move.

Consider the motion of a positive point charge in a region where there are simultaneous uniform eletric and magnetic field E=E_0hatj and B=B_0hatj . At time t=0 , this charge has velocity v in the x-y-plane making an angle theta with the x-axis. Which of the following option(s) is (are) correct for time tgt0? a. If theta=0^0 the charge moves in a circular path in the xy-plane. b.If theta=0^0 the charge undergoes helical motion with constant pitch along the y-axis. c. If theta=1 0^0 the charge undergoes helicalmotion with its pitch increasing with time along the y -axis. d. If theta=90^@ the charge undergoes linear but accelerated motion along the y -axis.

An electron accelerated by a potential difference V=1.0 kV moves in a uniform magnetic field at an angle alpha = 30^@ to the vector B whose modulus is B=29 mT. Find the pitch of the helical trajectory of the electron.

A proton moving with a constant velocity passes through a region of space without any changing its velocity. If E and B represent the electric and magnetic fields, respectively. Then, this region of space may have