Mobility of electron in N-type Ge is `5000 cm^(2)//"volt"` sec and conductivity `5 "mho/cm"`. If effect of holes is negligible then impurity concentration will be

An electric dipole is at 30° with uniform electric field of 2 xx 10^(5) N/C. The torque acting on it is 4 Nm. If length of dipole is 2 cm, then what will be the charge at one end of dipole ?

The number density of electron is a semiconductor is 8xx10^(13) cm^(-3) and number density of hole is 5xx10^(12) cm^(-3) then, (1) Which type of this semiconductor is? (2) How much is resistivity of it? (Mobility of electron is 23000 cm^(2)V^(-1)s^(-1) and mobility of hole is 100 cm^(2)V^(-1)s^(-1) and e=1.6xx10^(-19)C )

A block of mass 2 kg is connected with a spring of natural length 40 cm of force constant K=200 N//m . The cofficient of friction is mu=0.5 . When released from the given position, acceleration of block will be

What amount of inpurity of atomic density in added toform N-type semiconductor in Ge semiconductor of conductivity sigma is 5Omega^(-1)cm^(-1) Mobility of electron in N-type semiconductor is 3900 cm^(2)V^(-1)s^(-1) . Ignore conductivity due to hole. (e=1.6xx10^(-19)C)

In an intrinsic semiconductor the energy gap Eg is 1.2eV. Its hole mobility is much smaller than electron mobility and independent of temperature. What is the ratio between conductivity at 600K and that at 300K? Assume that the temperature dependence of intrinsic carrier concentration n_(i) is given by: n_(i) = n_(o) "exp" (-E_(g)/(2k_(B)T)) Where n_(0) is a constant.

In an intrinsic semiconductor the energy gap E_(g) is 1.2eV. Its hole mobility is much smaller than electron mobility and independent of temperature. What is the ratio between conductivity at 600K and that at 300K ? Assume that the temperature dependence of intrinsic carrier concentration n_(i) is given by n_(i)=n_(0)"exp"(-(E_(g))/(2k_(B)T)) where n_(0) is a constant.

The resistance of 0.5M solution of an electrolyte in a cell was found to be 50 Omega . If the electrodes in the cell are 2.2 cm apart and have an area of 4.4 cm^(2) then the molar conductivity (in S m^(2) mol^(-1)) of the solution is

A loop is formed by two parallel conductors connected by a solenoid with inductance L=2H and a conducting rod of mass m=80g, which can freely (without fricition) slide over the conductors. The conductors are located in a horizontal plane in a uniform vertical magnetic field with induction B=4T. The distance between the conductors is equal to l=4cm. At the moment t=0 the rod is imparted an initial velocity v_(0)=2 cm//s directed to the right. Find the amplitude (in cm) for the oscillations of conducting rod, if the electric resistance of the loop is negligible.