Counting Modes in 2 Dimensions

In a rectangular box of width and height the modes which have nodes at all boundaries are products of sinusoidal functions of the form , where and . Now the situation is a little more complicated, since is a vector. In fact, we call it the wavevector instead of the wave number; the wave number is then given by .

Why do we bother with the magnitude k instead of sticking to the intrinsically multidimensional vector ? Well, when we do kinematics we are often concerned with the kinetic energy, which is a scalar quantity depending only upon the magnitude of the momentum p (and upon the effective mass, if any) of the particle in question. Since we have discovered that photons (for example) are in some sense particles which have energy and momentum , we can conclude that (for massless particles only) and so, if all we really care about is the energy of a given mode, the only thing we need to know is its wave number, k .

But we still need to count up how many modes have (approximately) the same wavenumber k . This is where we have to return to the two-dimensional picture and begin talking in terms of k-space.

How many such states have (approximately) the same wavenumber k? This is a crucial question in many problems. To estimate the result we draw a ring in k-space with radius k and width dk. Recalling that only positive values of and are allowed (standing waves and all that), we only consider the upper right-hand quadrant of the circular ring; its "k-area" is thus . At a density of states per unit k-area, this gives or states in that ring quadrant. We can express this as a density of wavenumber magnitudes in terms of the distribution function which is defined as the number of allowed modes whose wavenumbers are within dk of a given k. Note that the number increases linearly with k, unlike in the 1D case where it is independent of k.