1-dimensional Ising model: Difference between revisions

Model: Consider a system with ${\displaystyle N}$ spins in a row.

The energy of the system will be given by

${\displaystyle U=-J\sum _{i=1}^{N-1}S_{i}S_{i+1}}$,

where each variable ${\displaystyle S_{j}}$ can be either -1 or +1.

The partition function of the system will be:

${\displaystyle Q_{N}=\sum _{\Omega ^{N}}\exp \left[K\sum _{i=1}^{N-1}S_{i}S_{i+1}\right]}$,

where ${\displaystyle \Omega ^{N}}$ represents the possible configuration of the N spins of the system, and ${\displaystyle K=J/k_{B}T}$

${\displaystyle Q_{N+1}=\sum _{S_{1}}\sum _{S_{2}}e^{kS_{1}S_{2}}\sum _{S_{3}}e^{KS_{2}S_{3}}\cdots \sum _{S_{N}}e^{KS_{N-1}S_{N}}\sum _{S_{N+1}}e^{KS_{N}S_{N+1}}}$

Performing the sum of the possible ${\displaystyle S_{N+1}}$ values we get:

${\displaystyle Q_{N+1}=\sum _{S_{1}}\sum _{S_{2}}e^{kS_{1}S_{2}}\sum _{S_{3}}e^{KS_{2}S_{3}}\cdots \sum _{S_{N}}e^{KS_{N-1}S_{N}}\left[2\cosh(KS_{n})\right]}$

${\displaystyle Q_{N+1}=\sum _{S_{1}}\sum _{S_{2}}e^{kS_{1}S_{2}}\sum _{S_{3}}e^{KS_{2}S_{3}}\cdots \sum _{S_{N}}e^{KS_{N-1}S_{N}}\left[2\cosh(K)\right]}$

Therefore:

${\displaystyle Q_{N+1}=\left(2\cosh K\right)Q_{N+1}}$

${\displaystyle Q_{N}=2^{N}\left(\cosh K\right)^{N-1}\approx (2\cosh K)^{N}}$

The Helmholtz free energy in the thermodynamic limit will be

${\displaystyle A=-Nk_{B}T\log \left(2\cosh K\right)}$