Project 4

First and second order phase transition in the Ising model of ferromagnetism

Introduction

Write a program which simulates via Metropolis Monte Carlo algorithm the 2D Ising model on a ${\displaystyle 64\times 64}$ square lattice with periodic boundary conditions. The model is assumed to describe a system placed in an applied external magnetic field ${\displaystyle H}$. The energy of a particular state of this system is then given by:

${\displaystyle E=-J\sum _{\langle i,j\rangle }S_{i}S_{j}-H\sum _{i}S_{i}}$

where ${\displaystyle \langle i,j\rangle }$ means that the sum runs over all pairs of nearest neighbor spins (attached to the lattice sites), and ${\displaystyle J}$ is the exchange coupling. Positive ${\displaystyle J>0}$ interaction between the spins leads to ferromagnetism, will negative ${\displaystyle J>0}$ gives rise to antiferromagnetism in the Ising model. Choose units so that ${\displaystyle |J|=1}$ and the Boltzmann constant is ${\displaystyle k_{B}=1}$. The free parameters of the model are then just the temperature ${\displaystyle T}$ and the applied field ${\displaystyle H}$.

Part I for both PHYS460 and PHYS660 students: First order phase transition in the ferromagnetic Ising model

Consider the ferromagnetic Ising model with ${\displaystyle J>0}$. Start from a case in which temperature is below the critical one ${\displaystyle T_{c}=2.269}$, such as ${\displaystyle T=1.0}$, and the field is large and pointing down, e.g., ${\displaystyle H=-5}$. The selected initial state of the Ising model should be the one in which all spins ${\displaystyle S_{i}=-1}$ are parallel to H, so that magnetization per spin is ${\displaystyle M=-1}$.

Sweep the magnetic field up to a large positive value ${\displaystyle H=5}$ and then back down to your starting value ${\displaystyle H=-5}$. Do this in steps of ${\displaystyle \delta H=0.5}$. After each change in the magnetic field ${\displaystyle H}$, allow sufficient Monte Carlo trials for the system to reach the equilibrium and thermalize.

For each value of ${\displaystyle H}$, calculate the mean energy per spin

${\displaystyle \langle E\rangle ={\frac {1}{N_{MC}}}\sum _{\alpha =1}^{N_{MC}}E_{\alpha }}$

the mean square energy per spin

${\displaystyle \langle E^{2}\rangle ={\frac {1}{N_{MC}}}\sum _{\alpha =1}^{N_{MC}}E_{\alpha }^{2}}$

the mean magnetization per spin

${\displaystyle \langle M\rangle ={\frac {1}{N_{MC}}}\sum _{\alpha =1}^{N_{MC}}M_{\alpha }}$

and the specific heat per spin

${\displaystyle C_{V}={\frac {1}{k_{B}T}}(\langle E^{2}\rangle -\langle E^{2}\rangle )}$

where we use the fluctuation-dissipation theorem to connect the specific heat to the fluctuations in energy . All sums in these expressions run are over ${\displaystyle N_{MC}}$ microstates generated by Monte Carlo simulation.

(a) Plot ${\displaystyle M}$ vs. ${\displaystyle H}$. You should see a discontinuous change in as H is increased, and a second discontinuous change in ${\displaystyle M}$ as ${\displaystyle H}$ is decreased back to its initial value. These discontinuous changes indicate a first order phase transition. Also note that the values of ${\displaystyle H}$ at which discontinuities occur are not identical. Such behavior is called hysteresis. Perform at least one thousand Monte Carlo time steps, where one time step is one complete pass through the lattice, at each value of the magnetic field.

(b) Repeat the calculations for a temperature ${\displaystyle T=4.0}$ above the critical point ${\displaystyle T_{c}}$. Is there a first order phase transition? Is there hysteresis? Provide a physical explanation of any difference in behavior for the two temperatures.

Part II for both PHYS460 and PHYS660 students: Second order phase transition in the ferromagnetic Ising model

Investigate the behavior of the specific heat ${\displaystyle C_{V}}$ as the temperature is increased through the critical value ${\displaystyle T_{c}}$ at both ${\displaystyle H=0}$, in which case we expect a second order or continuous paramagnet-ferromanget phase transition, and ${\displaystyle H\neq 0}$ , in which case we expect first order discontinous phase transtion. Repeat this calculation for increasing lattice size to see how the peak of ${\displaystyle C_{V}}$ around ${\displaystyle T_{c}}$ increases when ${\displaystyle H=0}$.

Part III for PHYS660 students only: Correlation length in the ferromagnetic Ising model

Part IV for PHYS660 students only: Second order phase transition in the antiferromagnetic Ising model

Compute temperature dependence of ${\displaystyle C_{V}}$, ${\displaystyle M}$, and ${\displaystyle \xi }$ in the absence of magnetic field ${\displaystyle H=0}$ for the antiferromagnetic Ising model with ${\displaystyle J=-1}$. The initial configuration can be chosen as all spins up ${\displaystyle S_{i}=+1}$ on a ${\displaystyle 64\times 64}$ lattice. What configuration of spins corresponds to the thermodynamic state below the Neel temperature ${\displaystyle T_{N}\approx 2.27}$? At the so-called Neel temperature this type of materials exhibit continous antiferromagnet-paramagnet phase transition.