In an intrinsic semiconductor the energy gap `E_(g) is 1.2 eV`. Its hole mobility is much smaller than electron mobility and independent of temperature. What is the ratio between conductivity at `600K` and `300K`? Assume that temperature dependence intrinstic concentration `n_(i)` is given by
`n_(i)=n_(0) exp ((-E_(g))/(2k_T))`, where `n_(0)` is a constant and `k_=8.62xx10^(-5)eV//K`.

In an intrinsic semiconductor, the energy gap E_(g) of an intrinsic semiconductor is 1.2 eV. Its hole mobility is very much smaller than electron mobility and is indepndent of temperature. What is the ratio between conductivity at 600K and at 300K? Assume that the temperature dependence of intrinsic concentraction n_(i) is expressed as, n_(i)=n_(o)e^(-E_(g)^(')//k_B)T , where n_(o) is constant and E_(g)^(') is an energy equal to E_(g)//2 , k_(B)=8.62xx10^(-6)eVK^(-1) .

The energy gap of pure Si is 1.1 eV The mobilities of electrons and holes are respectively 0.135 m^(2) V^(-1) s^(-1) and 0.048 m^(2) V^(-1) s^(-1) and can be taken as independent of temperature. The intrinsic carrier concentration is given by n_(i) = n_(0) e^(-Eg//2kT) . Where n_(0) is a constant, E_(g) The gap width and k The Boltmann's constant whose vaue is 1.38 xx 10^(-23) JK^(-1) The ratio of the electrical conductivities of Si at 600 K and 300 K is.

In an n-type semiconductor, the fermi level lies 0.3 eV below the conduction band at 300 K. If the temperature is increased to 330K, where does the new position of the Fermi level lie?

A semiconductor having electron and linear mobilities mu_(n) and mu_(p) respectively. If its intrinsic carrier density is n_(i) , then what will be the value of hole concentration P for which the conductivity will be maximum at a given temperature?

Internal energy of n_1 moles of hydrogen at temperature 150 K is equal to the in ternal energy of n_2 moles of helium at temperature 300 K The ratio of n_1//n_2 is

The conductivity of an intrinsic semiconductor depends of tempareture as (sigma)=(sigma_0)e^(-Delta E//2kT), where (sigma_0) is a constant.find the temperature at which the conductivity of an imtrinsic germanium semoconductor will be double of its value at T=300 K .Assume that the gap for germanium is 0.650 eV and remains constant as the temperature os increased.

find out the missing term C2E, E5H, G12K, I27N, ?

A pure semiconductor has equal electron and hole concentration of 10^(6)m^(-3) . Dopping by indium increases n_(h) to 4.5xx10^(22)m^(0k3) . What is n_(e) in the dopped semiconductor?

A pure semiconductor germanium or silicon, free of every impurity is called intrinsic semiconductor. A room temperature, a pure semiconductor has a very small number of current carriers (electrons and holes). Hence, its conductivity is low. When the impurity atoms of valence five or three are doped in a pure semiconductor, we get repectively n-type ot p-type extrinsic semiconductor. In case of a doped semiconductor. n_(e)n_(h)=n_(i)^(2) , where n_(e) and n_(h) are the number density of electrons and holes respectively and n_(i) is the number density of intrinsic charge carriers in a pure semiconductor. The conductivity of extrinsic semiconductor is much higher than that of intrinsic semiconductor. (i) Name two materials to be doped in pure semiconductor of silicon to get p-type semiconductor n-type semiconductor. (ii) What do you learn from the above study?

Show that the roots of the equation (1+x)^(2n)+(1-x)^(2n)=0 are given by x=+-i tan{(2k-1)(pi)/(2n)) where k=1,2,3,...n