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In solid state physics, a particle's effective
mass is the mass it seems to carry in the semiclassical model of transport in a crystal. It can be shown that, under most conditions, electrons and
holes in a crystal respond to
electric and magnetic fields almost as if they were free particles in a vacuum, but with a different mass. This mass is
usually stated in units of the ordinary mass of an electron me (9.11×10-31 kg).
Effective mass is defined by analogy with Newton's
second law F=m a. Using quantum mechanics it can be shown that for an electron in an external electric field E:
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where a is acceleration, h is Planck's constant, k is the wave number
(often loosely called momentum since k = p /
h), ε(k) is the energy as a function of k, or the dispersion relation as it
is often called. From the external electric field alone, the electron would experience a force of qE, where q
is the charge. Hence under the model that only the external electric field acts, effective mass
m* becomes:
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For a free particle, the dispersion relation is a quadratic, and so the
effective mass would be constant (and equal to the real mass). In a crystal, the situation is far more complex. The dispersion
relation is not even approximately quadratic, in the large scale. However, wherever a minimum occurs in the dispersion relation,
the minimum can be approximated by a quadratic curve in the small region around that minimum. Hence, for electrons which have
energy close to a minimum, effective mass is a useful concept.
In energy regions far away from a minimum, effective mass can be negative or even approach infinity. Effective mass, being generally dependent on direction (with respect to the crystal axes), is a tensor. However, for most calculations the various directions can be averaged out.
Effective mass should not be confused with reduced mass, which is a
concept from Newtonian mechanics. Effective mass can only be understood with
quantum mechanics.
Effective mass for some common semiconductors (for density of states calculations)
Reference: NSM archive
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