• The general mathematical formalism used to describe and solve the Heisenberg model and certain generalizations is developed in the article on the
Potts model. • In the
continuum limit the Heisenberg model (2) gives the following equation of motion :: \vec{S}_{t}=\vec{S}\wedge \vec{S}_{xx}. :This equation is called the
continuous classical Heisenberg ferromagnet equation or, more shortly, the Heisenberg model and is
integrable in the sense of soliton theory. It admits several integrable and nonintegrable generalizations like the
Landau-Lifshitz equation, the
Ishimori equation, and so on.
One dimension • In the case of a long-range interaction, J_{x,y}\sim |x-y|^{-\alpha} , the thermodynamic limit is well defined if \alpha >1 ; the magnetization remains zero if \alpha \ge 2 ; but the magnetization is positive, at a low enough temperature, if 1 (infrared bounds). • As in any 'nearest-neighbor'
n-vector model with free boundary conditions, if the external field is zero, there exists a simple exact solution.
Two dimensions • In the case of a long-range interaction, J_{x,y}\sim |x-y|^{-\alpha} , the thermodynamic limit is well defined if \alpha >2 ; the magnetization remains zero if \alpha \ge 4 ; but the magnetization is positive at a low enough temperature if 2 (infrared bounds). • Polyakov has conjectured that, as opposed to the
classical XY model, there is no
dipole phase for any T>0; namely, at non-zero temperatures the correlations cluster exponentially fast.
Three and higher dimensions Independently of the range of the interaction, at a low enough temperature the magnetization is positive. Conjecturally, in each of the low temperature extremal states the truncated correlations decay algebraically. ==See also==