The particle P shown in the figure has a mass m and a charge -q. Each horizontal plate has a surface area A potential difference `V=n((mg epsilon_(0)A)/(2qc))` should be applied to the combination to hold the particle p in equilibrium then find the value of n.

The particle P shown in the figure has a mass of 10 mg and a charge of -0.01 muC . Each plate has a surface area 10^(-2) m^2 on one side. What potential difference V should be applied to the combination to hold the particle P in equilibrium?

A charged particle of mass m and charge q is accelerated through a potential difference of V volts. It enters a region of uniform magnetic field which is directed perpendicular to the direction of motion of the particle. Find the radius of circular path moved by the particle in magnetic field.

A particle having charge + q is fixed at a point O and a second particle of mass m and having charge -q_(0) moves with constant speed in a circle of radius r about the charge +q. the energy required to be supplied to the moving charge to increase radius of the path to 2r is (q q_(0))/(n pi epsi_(0) r) . Find the value of n.

Each of the two block shown in the figure has mass m. The pulley is smooth and the coefficient of friction for all surfaces in contact is mu . A constant horizontal force P applied in two cases shown in such a way that block A start just sliding then the value of minimum force P in case-I and case-II is :

Only circular part of the wire shown in the figure has resistance sigma per unit length. The radii of the circles are r and R and /_POQ=alpha (in radian). If a potential difference V_(P)-V_(Q)=V is applied across the point P and Q , the magnetic field at point O is

A particle of mass = 2kg moves in simple harmonic motion and its potential energy U varies with position x as shown. The period of oscillation of the particle is (npi)/5 second. Find value of n.

Particle P shown in figure is moving in a circle of radius R=10 cm with linear speed v=2m//s Find the angular speed of particle about point O.

Two particles of equal masses m go round a circle of radius R under the action of their mutual gravitational attraction. The speed of each particle is v=sqrt((Gm)/(nR)) . Find the value of n.

A nonconducting disk of radius a and uniform positive surface charge density sigma is placed on the ground, with its axis vertical. A particle of mass m and positive charge q is dropped, along the axis of the disk, from a height H with zero initial velocity. The particle has q//m = 4 epsilon_(0) g// sigma . (i) Find the value of H if the particle just reaches the disk. (ii) Sketch the potential energy of the particle as a function of its height and find its equilibrium position.

A parallel plate capacitor has capacitance C. If the charges of the plates are Q and -3Q , find of the i. charges at the inner surfaces of the plates ii. Potential difference between the plates iii. charge flown if the plates are connected iv. energy lost by the capacitor in (iii.) v. charge flown if any plate is earthed.