Derive an expression for the resistivity of a good conductor, in terms of the relaxation time of electrons.

Answer the following: (i) Define the term drift velocity . (ii) On the basis of electron drift , derive an expression for resistivity of a conductor in terms of number density of free electrons and relaxation time. On what factors does resistivity of a coductor depend ? (iii) Why alloys like constantan and manganin are used for making standard restores ?

Derive the expression for the current density of a conductor in terms of the conductivity and applied electic field. Explain with reason how the mobility of electrons in a conductor changes when the potential difference applied is doubled, keeping the temperature of the conductor constant.

The dimensional formula for resistivity of conductor is

Derive the expression for drift velocity of free electron in terms of relaxation time and electric field applied across a conductor.

Derive the expression for drift velocity of free electron in terms of relaxation time and electric field applied across a conductor.

(a) Define the term 'conductivity' of a metallic wire. Write its SI unit. (b) Using the concept of free electrons in a conductor, derive the expression for the conductivity of a wire in te'rms of number density and relaxation time. Hence obtain the relation between current density and the applied electric field E.

(a) Why do the 'free electrons' , in a metal wire , flowing by themselves' not cause any current flow in the wire ? Define drift velocity' and obtain an expression for the current flowing in a wire, in terms of the 'drift velocity of the free electrons. (b) Use the above expression to show that the 'resistivity ' of the material of a wire is inversely proportional to the 'relaxation time' for the 'free electrons ' in the metal.

The resistance of a conductor depends on its

A good conductor of electricity: