Problem Set 3: Difference between revisions

Latest revision as of 20:40, 3 February 2009

Ising antiferromagnet on a ”bipartite” lattice

Hamiltonian:

Failed to parse (syntax error): {\displaystyle H = \frac{J}{2} \sum_{<ij>} S_i S_j -− h\sum_i S_i } ,

with the sum is over all nearest neighbor sites i and j. Note that now the interaction between spins minimizes the energy when the spins anti-allign, i.e. for Failed to parse (syntax error): {\displaystyle S_i = −- S_j\;} . A bipartite lattice is one that has two sublattices, so that each spin on sublattice A interacts only with some spin on the other sublattice B. In this case, in an antiferromagnetic state, each sublattice assumes a uniform magnetization. We can introduce the magnetization for each sublattice

$m_{A}=<S^{(A)}>;\;\;m_{B}=<S^{(B)}>.$

The average magnetization then can be written as

$m={\frac {1}{2}}(m_{A}+m_{B}),$

and the so-called ”staggered” magnetization is defined by the difference between the two sublattices

$m^{\dagger }={\frac {1}{2}}(m_{A}-m_{B}),$

For perfect ferromagnetic order $m=1\;$ , while for perfect antiferromagnetic order $m^{\dagger }=1$ .

(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 $m_{A}\;$ and $m_{B}\;$ , and express them through the order parameters $m\;$ and $m^{\dagger }$ .

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

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

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

@@ Line 5: / Line 5: @@
 <math> H = \frac{J}{2} \sum_{<ij>} S_i S_j  -− h\sum_i S_i </math>,
-with the sum is over all nearest neighbor sites i and j. Note that now the interaction between spins minimizes the energy when the spins anti-allign, i.e. for <math>S_i = −- S_j</math> . A bipartite lattice is one that has two sublattices, so that each spin on sublattice A interacts only with some spin on the other sublattice B. In this case, in an antiferromagnetic state, each sublattice assumes a uniform magnetization. We can introduce the magnetization for each sublattice
+with the sum is over all nearest neighbor sites i and j. Note that now the interaction between spins minimizes the energy when the spins anti-allign, i.e. for <math>S_i = −- S_j\;</math> . A bipartite lattice is one that has two sublattices, so that each spin on sublattice A interacts only with some spin on the other sublattice B. In this case, in an antiferromagnetic state, each sublattice assumes a uniform magnetization. We can introduce the magnetization for each sublattice
-<math>m_A = < S^{(A)} >; \; \; m_A = < S^{(A)} >.</math>
+<math>m_A = < S^{(A)} >; \; \; m_B = < S^{(B)} >.</math>
@@ Line 18: / Line 18: @@
 <math>m^{\dagger} = \frac{1}{2} (m_A - m_B ),</math>
-For perfect ferromagnetic order <math>m = 1</math>, while for perfect antiferromagnetic order
+For perfect ferromagnetic order <math>m = 1\;</math>, while for perfect antiferromagnetic order
 <math>m^{\dagger} = 1</math>.
-(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 <math>m_A</math> and <math>m_B</math>, and express them through the
+(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 <math>m_A\;</math> and <math>m_B\;</math>, and express them through the
-order parameters <math>m</math> and <math>m^{\dagger}</math>.
+order parameters <math>m\;</math> and <math>m^{\dagger}</math>.
-(2) Assume that <math>h = 0</math>, so that <math>m = 0</math>, and solve the mean-field equations by expanding in <math>m^{\dagger}</math>. Determine the Neel (ordering) temperature, and calculate the order-parameter exponent.
+(2) Assume that <math>h = 0\;</math>, so that <math>m = 0\;</math>, and solve the mean-field equations by expanding in <math>m^{\dagger}</math>. Determine the Neel (ordering) temperature, and calculate the order-parameter exponent <math>\beta</math> .
-(3) Now consider a small external field <math>h > 0</math>, so that both order parameters can assume a nonzero value (Note: <math>m</math> will be small). By keeping only the leading terms in <math>h</math> and <math>m</math>, calculate the uniform spin susceptibility <math>\chi = \partial m/ \partial h</math>, as a function of temperature. Show that <math>\chi</math> has a cusp around <math>T_N</math>.
+(3) Now consider a small external field <math>h > 0\;</math>, so that both order parameters can assume a nonzero value (Note: <math>m\;</math> will be small). By keeping only the leading terms in <math>h\;</math> and <math>m\;</math>, calculate the uniform spin susceptibility <math>\chi = \partial m/ \partial h</math>, as a function of temperature. Plot <math>\chi\;</math> as a function of temperature, and show that it has a cusp around <math>T_N\;</math>.
-(4) Imagine adding a ”staggered” external field <math>h^{\dagger}</math>, which would be positive on sublattice A, but would be negative on sublattice B. Concentrate on the system with no uniform field <math>(h = 0)</math>, and determine the behavior of the staggered susceptibility
+(4) Imagine adding a ”staggered” external field <math>h^{\dagger}</math>, which would be positive on sublattice A, but would be negative on sublattice B. Concentrate on the system with no uniform field <math>(h = 0)\;</math>, and determine the behavior of the staggered susceptibility <math>\chi^{\dagger}= \partial m^{\dagger} / \partial h^{\dagger} </math>
+. Show that <math>\chi^{\dagger}</math> blows up at the Neel temperature.
-<math>\chi^{\dagger}= \partial m^{\dagger} / \partial h^{\dagger} </math>
-.
-Show that <math>\chi^{\dagger}</math> blows up at the Neel temperature.

Problem Set 3: Difference between revisions

Latest revision as of 20:40, 3 February 2009

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