statistical mechanics In physics, statistical mechanics is a mathematical framework that applies statistical methods and probability theory to large assemblies of microscopic entities. Sometimes called statistical physics or statistical thermodynamics, its applicati ...

, the hard hexagon model is a 2-dimensional lattice model of a gas, where particles are allowed to be on the vertices of a triangular lattice but no two particles may be adjacent. The model was solved by , who found that it was related to the Rogers–Ramanujan identities.

The partition function of the hard hexagon model

The hard hexagon model occurs within the framework of the

grand canonical ensemble In statistical mechanics, the grand canonical ensemble (also known as the macrocanonical ensemble) is the statistical ensemble that is used to represent the possible states of a mechanical system of particles that are in thermodynamic equilibri ...

, where the total number of particles (the "hexagons") is allowed to vary naturally, and is fixed by a

chemical potential In thermodynamics, the chemical potential of a Chemical specie, species is the energy that can be absorbed or released due to a change of the particle number of the given species, e.g. in a chemical reaction or phase transition. The chemical potent ...

. In the hard hexagon model, all valid states have zero energy, and so the only important thermodynamic control variable is the ratio of chemical potential to temperature ''μ''/(''kT''). The exponential of this ratio, ''z'' = exp(''μ''/(''kT'')) is called the activity and larger values correspond roughly to denser configurations. For a triangular lattice with ''N'' sites, the grand partition function is :

\displaystyle \mathcal Z(z) = \sum_n z^n g(n,N) = 1+Nz+ \tfracN(N-7)z^2+\cdots

where ''g''(''n'', ''N'') is the number of ways of placing ''n'' particles on distinct lattice sites such that no 2 are adjacent. The function κ is defined by :

\kappa(z) = \lim_ \mathcal Z(z)^ = 1+z-3z^2+\cdots

so that log(κ) is the free energy per unit site. Solving the hard hexagon model means (roughly) finding an exact expression for κ as a function of ''z''. The mean density ρ is given for small ''z'' by :

\rho= z\frac  =z-7z^2+58z^3-519z^4+4856z^5+\cdots.

The vertices of the lattice fall into 3 classes numbered 1, 2, and 3, given by the 3 different ways to fill space with hard hexagons. There are 3 local densities ρ₁, ρ₂, ρ₃, corresponding to the 3 classes of sites. When the activity is large the system approximates one of these 3 packings, so the local densities differ, but when the activity is below a critical point the three local densities are the same. The critical point separating the low-activity homogeneous phase from the high-activity ordered phase is

z_c = (11+5\sqrt5)/2 = \phi^5 = 11.09017....

with

golden ratio In mathematics, two quantities are in the golden ratio if their ratio is the same as the ratio of their summation, sum to the larger of the two quantities. Expressed algebraically, for quantities and with , is in a golden ratio to if \fr ...

''φ''. Above the critical point the local densities differ and in the phase where most hexagons are on sites of type 1 can be expanded as :

\rho_1 = 1-z^-5z^-34z^-267z^-2037z^-\cdots

\rho_2=\rho_3 = z^ + 9z^ + 80z^ +  965z^-\cdots.

Solution

The solution is given for small values of ''z'' < ''z''_''c'' by :

\displaystyle z=\frac

\kappa = \frac 
\prod_ \frac

\rho =\rho_1=\rho_2=\rho_3= \frac

where :

G(x) = \prod_\frac

H(x) = \prod_\frac

P(x) = \prod_(1-x^) = Q(x)/Q(x^2)

Q(x) = \prod_(1-x^n).

For large ''z'' > ''z''_''c'' the solution (in the phase where most occupied sites have type 1) is given by :

\displaystyle z=\frac

\kappa = x^\frac 
\prod_ \frac

\rho_1 = \frac

\rho_2=\rho_3 = \frac

R=\rho_1-\rho_2= \frac.

The functions ''G'' and ''H'' turn up in the Rogers–Ramanujan identities, and the function ''Q'' is the Euler function, which is closely related to the Dedekind eta function. If ''x'' = e^2πiτ, then ''x''^−1/60''G''(''x''), ''x''^11/60''H''(''x''), ''x''^−1/24''P''(''x''), ''z'', κ, ρ, ρ₁, ρ₂, and ρ₃ are modular functions of τ, while ''x''^1/24''Q''(''x'') is a modular form of weight 1/2. Since any two modular functions are related by an algebraic relation, this implies that the functions ''κ'', ''z'', ''R'', ''ρ'' are all algebraic functions of each other (of quite high degree) . In particular, the value of ''κ''(1), which Eric Weisstein dubbed the hard hexagon entropy constant , is an

algebraic number In mathematics, an algebraic number is a number that is a root of a function, root of a non-zero polynomial in one variable with integer (or, equivalently, Rational number, rational) coefficients. For example, the golden ratio (1 + \sqrt)/2 is ...

of degree 24 equal to 1.395485972... ().

Related models

The hard hexagon model can be defined similarly on the square and honeycomb lattices. No exact solution is known for either of these models, but the critical point ''z''_c is near for the square lattice and for the honeycomb lattice; ''κ''(1) is approximately 1.503048082... () for the square lattice and 1.546440708... for the honeycomb lattice .

References

* * * * * Exton, H. (1983), ''q-Hypergeometric Functions and Applications'', New York: Halstead Press, Chichester: Ellis Horwood * * * *

External links

*{{mathworld, urlname=HardHexagonEntropyConstant, title=Hard Hexagon Entropy Constant Exactly solvable models Statistical mechanics Lattice models Modular forms Algebraic numbers