Figure shows the path of an electron in a region of uniform magnetic field. The path consists of two straight sections, each between a pair of uniformly charged plates and two half circles. The electric field exists only between the plates

Two thin infinite parallel plates have uniform charge densities + sigma and - sigma . The electric field in the space between them is

The path of a charged particle in a uniform magnetic field, when the velocity and the magnetic field are perpendicular to each other is a

the figure shows the path of A positively charged particle through a rectangular region of uniform electric field as shown in the figure. the direction of deflection of particle 2, 3 and 4 is

Two plates are 2cm apart, a potential difference of 10 volt is applied between them, the electric field between the plates is

A charged particle enters a region of uniform magnetic field at an angle of 85^@ to the magnetic line of force. The path of the particle is a circle. Is this statement true or false?

A charged particle having kinetic energy E enters normally a region of uniform magnetic field between two plates P_(1) and P_(2) as shown in the figure. If the particle just misses hitting the plate P_(2) , then the magnetic field B in the region between the plates is

Assertion If the path of a charged particle in a region of uniform electric and magnetic field is not a circle, then its kinetic energy may remain constant. Reason In a combined electric and magnetic field region a moving charge experiences a net force F=qE+q(VxxB), where symbols have their usual meanings.

(a) A closed loop is held stationary in the magnetic field between the north and south poles of two permanent magnets held fixed. Can we hope to generate current in the loop by using very strong magnets? (b) A closed loop moves normal to the constant electric field between the plates of a large capacitor. Is a current induced in the loop (i) when it is wholly inside the region between the capacitor plates (ii) when it is partially outside the plates of the capacitor? The electric field is normal to the plane of the loop. (c) A rectangular loop and a circular loop are moving out of a uniform magnetic field region (Fig. 6.8) to a field-free region with a constant velocity v. In which loop do you expect the induced emf to be constant during the passage out of the field region? The field is normal to the loops. (d) Predict the polarity of the capacitor in the situation described by Fig. 6.9.

Figure shows two metallic plates A and B placed parallel to each other at a seperation d. A uniform electric field E exists between the plates in the direction from plate B to plate A. Find the potential difference between the plates.

Two large conducting plates X and Y. each having large surface area A (on one side), are placed parallel to each other as shown in figure (30-E7). The plate X is given a charge Q whereas the other is neutral. Find (a) the surface charge density at the inner surface of the plates X, (b) the electric field at a point to the left of the plates, (c) the electric field at a point in between the plates and (d) the electric field at a point to the right of the plates.