Hypernetted Chain Equation
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In
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 hypernetted-chain equation is a closure relation to solve the Ornstein–Zernike equation which relates the direct correlation function to the total correlation function. It is commonly used in fluid theory to obtain e.g. expressions for the radial distribution function. It is given by: : \ln y(r_) =\ln g(r_) + \beta u(r_) =\rho \int \left (r_) - \ln g(r_) - \beta u(r_)\righth(r_) \, d \mathbf, \, where \rho = \frac is the number density of molecules, h(r) = g(r)-1, g(r) is the radial distribution function, u(r) is the direct interaction between pairs. \beta = \frac with T being the
Thermodynamic temperature Thermodynamic temperature, also known as absolute temperature, is a physical quantity which measures temperature starting from absolute zero, the point at which particles have minimal thermal motion. Thermodynamic temperature is typically expres ...
and k_ the
Boltzmann constant The Boltzmann constant ( or ) is the proportionality factor that relates the average relative thermal energy of particles in a ideal gas, gas with the thermodynamic temperature of the gas. It occurs in the definitions of the kelvin (K) and the ...
.


Derivation

The direct correlation function represents the direct correlation between two particles in a system containing ''N'' − 2 other particles. It can be represented by : c(r)=g_(r) - g_(r) \, where g_(r)=g(r) = \exp \beta w(r)/math> (with w(r) the potential of mean force) and g_(r) is the radial distribution function without the direct interaction between pairs u(r) included; i.e. we write g_(r)=\exp\. Thus we ''approximate'' c(r) by : c(r)=e^- e^. \, By expanding the indirect part of g(r) in the above equation and introducing the function y(r)=e^g(r) (= g_(r) ) we can approximate c(r) by writing: : c(r)=e^-1+\beta (r)-u(r) \, = g(r)-1-\ln y(r) \, = f(r)y(r)+ (r)-1-\ln y(r)\,\, (\text), with f(r) = e^-1. This equation is the essence of the hypernetted chain equation. We can equivalently write : h(r) - c(r) = g(r) - 1 -c(r) = \ln y(r). If we substitute this result in the Ornstein–Zernike equation : h(r_)- c(r_) = \rho \int c(r_)h(r_)d \mathbf_, one obtains the hypernetted-chain equation: : \ln y(r_) =\ln g(r_) + \beta u(r_) =\rho \int \left (r_) -\ln g(r_) - \beta u(r_)\righth(r_) \, d \mathbf. \,


See also

* Classical-map hypernetted-chain method * Percus–Yevick approximation – another closure relation * Ornstein–Zernike equation Statistical mechanics {{statisticalmechanics-stub