An electron having a kinetic energy of `400 eV` circulates in a path of radius `20 cm` in a magnetic field.Find the magnetic field and the number of revolutions per second made by the electron.

An electron having a kinetic energy of 100eV circulates in a path of radius 10cm in a magnetic field. Find the magnetic field and the number of revolutons per second made by the electron.

An electron having kinetic energy 10eV is circulating in a path of radius 0.1 m in an external magnetic field of intensity 10^(-4) T. The speed of the electron will be

Refer to the figure. Rectangle PQRS represents the cross section of a uniform magnetic field region of 0.20 T. An electron is projected at a speed of V=2.0xx10^(6)m//s into the region at an angle of 30^(@) to the direction of the mangetic field. The length of the magnetic field region is 0.01 m. Find the number of revolutions made by the electron before it leaves the magnetic field region.

An electron having kinetic energy T is moving in a circular orbit of radius R prependicular to a uniform magnetic field induction barB . If kinetic energy is double and magentic field induction is triple, the radius will becomes :

An electron is moving with a velocity of 10^(7) ms^(-1) on a circular path of radius 0.57 cm in a magnetic field of 10^(-2) Wbm^(-2) . Find the value of e//m for the electron.

An electron is moving on a circular path of radius r with speed v in a transverse magnetic field B. e/m for it will be

An electron having kinetic energy K is moving i a circular orbit of radius R perpendicular to a uniform magnetic induction. If kinetic energy is douled and magnetic induction tripled, the radius will become