George Domingo

Semiconductor Basics


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Schematic illustration of two hydrogen atoms being so close to form a single system (right), the Pauli exclusion principle requires that their energy levels be different.

      Energy bands explain the difference between an insulator, a metal, and a semiconductor. Everything depends on how many electrons are in the atom's outer energy level, that is, the valence band level, how the atoms share electrons when they form a solid, and what the separation is between the bands.

      When a, the interatomic distance, is very large (infinity) at the right of Figure 2.4, the atoms are so far separated that the electrons do not interact with each other. When they are that separated, all the individual atoms have the same energy levels. As the distance between atoms gets smaller, at some point the atoms (beginning with those in the outer orbits) start interacting, and the energy levels begin broadening to satisfy Pauli's exclusion principle. Nature determines the actual interatomic distance, a, in a solid. In silicon, for example, the interatomic distance (called the lattice constant in crystals) is 5.431 angstroms (5.431 Å: an A with a tiny o on top). An angstrom is equal to 1 × 10−10 m.

      Note in Figure 2.4 that as the interatomic distance gets smaller, the levels start separating in different ways. At the solid's equilibrium spacing, the separation between the first and second bands, A and B, is very large; between the second and third levels, B and C, there is a separation, but it is much smaller. Finally, there is no separation between the third, fourth, and fifth bands (C, D, and E). They encroach on each other. This is expected, because the electrons in the outer bands start to interact before the inner ones do.

Schematic illustration of atomic levels split into bands as the interatomic distance between atoms becomes smaller, forming energy bands and energy gaps as soon as they are close enough to interact with each other.

      1 The valence band is full of electrons; there is no space for any more.

      2 The valence band is not full of electrons. There are empty spaces that can accept additional electrons.

      3 The conduction band is separated from the valence band with a small energy gap, such as the separation of levels B and C.

      4 The conduction band is separated from the valence band with a large energy gap, such as that between A and B.

      5 There is no separation at all between two bands such as C and D or D and E. The conduction band touches or falls inside the valence band.

      Let's take a look at each of these cases.

Schematic illustration of an insulator, the valence band is full of electrons, the conduction band is empty, and the separation between the two bands is very large.

      At this point, I would like to clarify the concept of bands, which can sometimes be confusing. The bands are not a physical location where electrons reside, just as earth's orbit is not a railroad track or a circular road on top of which the earth travels. A cannonball follows a parabolic path even though there is no “path,” pipe, road, or track that the ball rolls over. The concept of energy bands is similar. The electrons are anywhere in the material, but they have energies with values restricted to certain allowed ranges – energy ranges that we call bands. The electrons are not allowed, under any circumstances, to have energy between the highest energy of the valence band and the lowest energy of the conduction band.