Solution to Set 3

Ising antiferromagnet on a ”bipartite” lattice

This assignment corresponds to Section 8.3 and 8.4 in the Solid State Physics book. It deals with the topics of Magnetic Order.

Given Informatin

• Hamiltonian Failed to parse (syntax error): {\displaystyle H = \frac{J}{2} \sum_{<ij>} S_i S_j -− h\sum_i S_i } ,
• Bipartite lattice: a lattice with 2 sublattices, so that each spin on sublattice A interacts only with some spin on the other sublattice B. In an antiferromagnetic state, each sublattice assumes a uniform magnetization.
• Magnetization for Lattice A: ${\displaystyle m_{A}=<S^{(A)}>}$
• Magnetization for Lattice B: ${\displaystyle m_{B}=<S^{(B)}>}$
• Average magnetization: ${\displaystyle m={\frac {1}{2}}(m_{A}+m_{B}),}$
• "Staggered” magnetization: ${\displaystyle m^{\dagger }={\frac {1}{2}}(m_{A}-m_{B}),}$ (Note: It's the difference between the two sublattices)
• ${\displaystyle m=1\;}$ for perfect ferromagnetic order
• ${\displaystyle m^{\dagger }=1}$ for perfect antiferromagnetic order

Part 1

(1) Use Weiss mean-field decoupling to replace one of the spins in the Hamiltonian by its thermal average. The Weiss field experienced by a given spin is then proportional to the sublattice magnetization on the other sublattice. Write down self-consistent equations for ${\displaystyle m_{A}\;}$ and ${\displaystyle m_{B}\;}$, and express them through the order parameters ${\displaystyle m\;}$ and ${\displaystyle m^{\dagger }}$.

First, Weiss mean field decoupling

Part 2

(2) Assume that ${\displaystyle h=0\;}$, so that ${\displaystyle m=0\;}$, and solve the mean-field equations by expanding in ${\displaystyle m^{\dagger }}$. Determine the Neel (ordering) temperature, and calculate the order-parameter exponent.

Part 3

(3) Now consider a small external field ${\displaystyle h>0\;}$, so that both order parameters can assume a nonzero value (Note: ${\displaystyle m\;}$ will be small). By keeping only the leading terms in ${\displaystyle h\;}$ and ${\displaystyle m\;}$, calculate the uniform spin susceptibility ${\displaystyle \chi =\partial m/\partial h}$, as a function of temperature. Plot ${\displaystyle \chi \;}$ as a function of temperature, and show that it has a cusp around ${\displaystyle T_{N}\;}$.

Part 4

(4) Imagine adding a ”staggered” external field ${\displaystyle h^{\dagger }}$, which would be positive on sublattice A, but would be negative on sublattice B. Concentrate on the system with no uniform field ${\displaystyle (h=0)\;}$, and determine the behavior of the staggered susceptibility ${\displaystyle \chi ^{\dagger }=\partial m^{\dagger }/\partial h^{\dagger }}$. Show that ${\displaystyle \chi ^{\dagger }}$ blows up at the Neel temperature.