Abstract
Electron dynamics in crystalline semiconductors is described by distinguishing between an instantaneous velocity related to electron's momentum and an average velocity related to its quasi-momentum in a periodic potential. It is shown that the electron velocity used in the theory of electron transport and free-carrier optics is the average electron velocity, not the instantaneous velocity. An e ective mass of charge carriers in solids is considered and it is demonstrated that, in contrast to the acceleration mass introduced in textbooks, it is a velocity mass relating carrier velocity to its quasi-momentum that is a much more useful physical quantity. Among other advantages, the velocity mass is a scalar for spherical but nonparabolic energy bands (k), whereas the acceleration mass is not a scalar. Important applications of the velocity mass are indicated. A two-band k · p model is introduced as the simplest example of a band structure that still keeps track of the periodic lattice potential. It is remarked that the two-band model, adequately describing narrow-gap semiconductors (including zero-gap graphene), strongly resembles the special theory of relativity. Instructive examples of the semi-relativistic analogy are given. The presentation has both scienti c and pedagogical aspects.
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