Figure shows a uniform magnetic field of induction B confined to a cylindrical volume of radius R. B is increasing at a constant rate of 100 T/s. What is instantaneous acceleration experienced by a charged particle placed at C distant r from centre. Assume r = 5 m.
(Given `(q)/(m) = 1.6 xx10^(-2)` C/kg)

Figures show a uniform magnetic field B condfirned to ta cylinderical bolume of radius R. If B is increasing aty constant rate of 0.01T/s. Instantaneous acceleration experienced by electron at r=10cm (ltR) as shown in the figure.

Figure 30-61 shows a uniform magnetic field vecB confined to a cylindrical volume of radius R. The magnitude of vecB is decreasing at a constant rate of 10 mT/s. In unit-vector notation, what is the initial acceleration of an electron released at (a) point a (radial distance r = 5.0 cm), (b) point b (r = 0), and (c) point c (r = 5.0 cm)?

A uniform magnetic field of induction B is confined to a cyclindrical region of radius R . The magnetic field is increasing at a constant rate of dB//dt (tesla // second). A charge q of mass m , placed at the point P on the periphery of the fixed experiences an acceleration :

A uniform magentic field of induction B is confined in a cyclinderical region of radius R . If the field is incresing at a constant rate of (dB)/(dt)= alpha T//s , then the intensity of the electric field induced at point P , distant r from the axis as shown in the figure is proportional to :

A uniform magneitc field B fills a cylindrical volume of radius R, A metal rod of length l is placed as shown. If B is changing at the rate of dB/dt, the emf that is produced by the changing magnetic field is xi here p = sqrt(R^(2) - ((l)/(2))^(2)) . then

A cylindrical space of radius R is filled with a uniform magnetic induction parallel to the axis of the cylinder. If B charges at a constant rate, the graph showin the variation of induced electric field with distance r from the axis of cylinder is