Doubly periodic function: Difference between revisions

A Van Hove singularity is a singularity (non-smooth point) in the density of states (DOS) of a crystalline solid. The wavevectors at which Van Hove singularities occur are often referred to as critical points of the Brillouin zone. (The critical point found in phase diagrams is a completely separate phenomenon.) For three-dimensional crystals, they take the form of kinks (where the density of states is not differentiable). The most common application of the Van Hove singularity concept comes in the analysis of optical absorption spectra. The occurrence of such singularities was first analyzed by the Belgian physicist Léon Van Hove in 1953 for the case of phonon densities of states.^[1]

Theory

Consider a one-dimensional lattice of N particles, with each particle separated by distance a, for a total length of L = Na. A standing wave in this lattice will have a wave number k of the form

${\displaystyle k={\frac {2\pi }{\lambda }}=n{\frac {2\pi }{L}}}$

where ${\displaystyle \lambda }$ is wavelength, and n is an integer. (Positive integers will denote forward waves, negative integers will denote reverse waves.) The smallest wavelength possible is 2a which corresponds to the largest possible wave number ${\displaystyle k_{max}=\pi /a}$ and which also corresponds to the maximum possible |n|: ${\displaystyle n_{max}=L/2a}$. We may define the density of states g(k)dk as the number of standing waves with wave vector k to k+dk:^[2]

${\displaystyle g(k)dk=dn={\frac {L}{2\pi }}\,dk}$

Extending the analysis to wavevectors in three dimensions the density of states in a box will be

${\displaystyle g({\vec {k}})d^{3}k=d^{3}n={\frac {L^{3}}{(2\pi )^{3}}}\,d^{3}k}$

where ${\displaystyle d^{3}k}$ is a volume element in k-space, and which, for electrons, will need to be multiplied by a factor of 2 to account for the two possible spin orientations. By the chain rule, the DOS in energy space can be expressed as

${\displaystyle dE={\frac {\partial E}{\partial k_{x}}}dk_{x}+{\frac {\partial E}{\partial k_{y}}}dk_{y}+{\frac {\partial E}{\partial k_{z}}}dk_{z}={\vec {\nabla }}E\cdot d{\vec {k}}}$

where ${\displaystyle {\vec {\nabla }}}$ is the gradient in k-space.

The set of points in k-space which correspond to a particular energy E form a surface in k-space, and the gradient of E will be a vector perpendicular to this surface at every point.^[3] The density of states as a function of this energy E is:

${\displaystyle g(E)dE=\iint _{\partial E}g({\vec {k}})\,d^{3}k={\frac {L^{3}}{(2\pi )^{3}}}\iint _{\partial E}dk_{x}\,dk_{y}\,dk_{z}}$

where the integral is over the surface ${\displaystyle \partial E}$ of constant E. We can choose a new coordinate system ${\displaystyle k'_{x},k'_{y},k'_{z}\,}$ such that ${\displaystyle k'_{z}\,}$ is perpendicular to the surface and therefore parallel to the gradient of E. If the coordinate system is just a rotation of the original coordinate system, then the volume element in k-prime space will be

${\displaystyle dk'_{x}\,dk'_{y}\,dk'_{z}=dk_{x}\,dk_{y}\,dk_{z}}$

We can then write dE as:

${\displaystyle dE=|{\vec {\nabla }}E|\,dk'_{z}}$

and, substituting into the expression for g(E) we have:

${\displaystyle g(E)={\frac {L^{3}}{(2\pi )^{3}}}\iint {\frac {dk'_{x}\,dk'_{y}}{|{\vec {\nabla }}E|}}}$

where the ${\displaystyle dk'_{x}\,dk'_{y}}$ term is an area element on the constant-E surface. The clear implication of the equation for ${\displaystyle g(E)}$ is that at the ${\displaystyle k}$-points where the dispersion relation ${\displaystyle E({\vec {k}})}$ has an extremum, the integrand in the DOS expression diverges. The Van Hove singularities are the features that occur in the DOS function at these ${\displaystyle k}$-points.

A detailed analysis^[4] shows that there are four types of Van Hove singularities in three-dimensional space, depending on whether the band structure goes through a local maximum, a local minimum or a saddle point. In three dimensions, the DOS itself is not divergent although its derivative is. The function g(E) tends to have square-root singularities (see the Figure) since for a spherical free electron Fermi surface

${\displaystyle E=\hbar ^{2}k^{2}/2m}$ so that ${\displaystyle |{\vec {\nabla }}E|=\hbar ^{2}k/m=\hbar {\sqrt {\frac {2E}{m}}}}$.

In two dimensions the DOS is logarithmically divergent at a saddle point and in one dimension the DOS itself is infinite where ${\displaystyle {\vec {\nabla }}E}$ is zero.

Experimental observation

The optical absorption spectrum of a solid is most straightforwardly calculated from the electronic band structure using Fermi's Golden Rule where the relevant matrix element to be evaluated is the dipole operator ${\displaystyle {\vec {A}}\cdot {\vec {p}}}$ where ${\displaystyle {\vec {A}}}$ is the vector potential and ${\displaystyle {\vec {p}}}$ is the momentum operator. The density of states which appears in the Fermi's Golden Rule expression is then the joint density of states, which is the number of electronic states in the conduction and valence bands that are separated by a given photon energy. The optical absorption is then essentially the product of the dipole operator matrix element (also known as the oscillator strength) and the JDOS.

The divergences in the two- and one-dimensional DOS might be expected to be a mathematical formality, but in fact they are readily observable. Highly anisotropic solids like graphite (quasi-2D) and Bechgaard salts (quasi-1D) show anomalies in spectroscopic measurements that are attributable to the Van Hove singularities. Van Hove singularities play a significant role in understanding optical intensities in single-walled nanotubes (SWNTs) which are also quasi-1D systems. The Dirac point in graphene is a Van-Hove singularity that can be seen directly as a peak in electrical resistance, when the graphene is charge-neutral.

Notes