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class: center, middle

# An efficient cluster algorithm for spin systems in a symmetry-breaking field

## Jaron Kent-Dobias &amp; James Sethna

### Cornell University

## 9 March 2018

---

# Spin systems

Described by Hamiltonians whose degrees of freedom are spins `\(s\in X\)`

$$\mathcal H=-\sum_{\langle ij\rangle}Z(s_i,s_j)-\sum_iH(s_i)$$

for \\(Z\\) invariant under the action of rotations \\(r\in R\\), or \\(Z(r\cdot s,r\cdot t)=Z(s,t)\\).

<table style="border-collapse: collapse; width: 100%; margin: auto;">
  <thead style="border-bottom: 2px solid #000;">
    <tr>
      <td class="first"></td><td><i>X</i><td><i>R</i></td><td>Group Action</td><td>\(Z(s,t)\)</td><td>\(H(s)\)</td>
    </tr>
  </thead>
  <tbody>
    <tr>
      <td class="first">Ising model</td><td>\(\{-1,1\}\)</td><td>ℤ/2ℤ</td><td>\(0\cdot s\mapsto s\)<br>\(1\cdot s\mapsto-s\)</td><td>\(s\times t\)</td><td>\(Hs\)</td>
    </tr>
    <tr>
      <td class="first">Order-\(n\) model</td><td>\(S^n\)</td><td>\(\mathop{\mathrm{O}}(n)\)</td><td>\(O\cdot s\mapsto Os\)</td><td>\(s^{\mathrm T}t\)</td><td>\(H\cdot s\)</td>
    </tr>
    <tr>
      <td class="first">Potts model</td><td>ℤ/<i>q</i>ℤ</td><td>ℤ/<i>q</i>ℤ</td><td>\(m\cdot s\mapsto{(s+m)}\pmod q\)</td><td>\(\delta(s,t)\)</td><td>\(\sum_mH_m\delta(m,s)\)</td>
    </tr>
    <tr>
      <td class="first">Clock model</td><td>ℤ/<i>q</i>ℤ</td><td>ℤ/<i>q</i>ℤ</td><td>\(m\cdot s\mapsto{(s+m)}\pmod q\)</td><td>\(\cos(2\pi\frac{s-t}q)\)</td><td>\(\sum_mH_m\cos(2\pi\frac{s-m}q)\)</td>
    </tr>
  </tbody>
</table>

Relatively simple with extremely rich behavior, phase transition galore!

---

class: split-40

# Local Monte Carlo: Not Great

.column[

  Standard approach to modelling arbitrary stat mech system: metropolis.
  
  1. Pick random spin.
  2. Pick random rotation \\(r\in R\\).
  3. Compute change in energy \\(\Delta\mathcal H\\) resulting from taking \\(s\\) to \\(r\cdot s\\).
  4. Take \\(s\\) to \\(r\cdot s\\) with probability \\(\max\\{1,e^{-\beta\Delta\mathcal H}\\}\\).


Problem: Scales very poorly near phase transitions.

Correlation time `\(\tau\sim L^z\)` at critical point, `\(\tau\sim t^{-z/\nu}\)`
  approaching it.

  `\(z\)` takes large integer values for Ising, order-`\(n\)`, Potts model critical regions.
  ]

  .column[
<video width="320" height="320"><source src="figs/metropolis_ising_zerofield.webm" type="video/webm"></video>
]

---

class: split-40

# Wolff: wow, what a solution

.column[
Non-local updates!

  1. Pick random spin `\(s\in X\)`, add to cluster.
  2. Pick random rotation `\(r\in R\)`.
  3. For every neighboring spin `\(t\)`, add to cluster with probability
      `\(\min\{0,1-e^{-\beta(Z(r\cdot s,r\cdot t)-Z(r\cdot s,t))}\}\)`.
  4. Repeat 3 for every new spin added to cluster.
  5. Transform entire cluster by applying the action of rotation `\(r\)`.

Relies on symmetry of *Z* under group of rotations.

Fast near the critical point: early studies thought `\(z\)` was zero for 2D Ising, actually
  0.1–0.4, below one for models listed here.

  ]

  .column[
<video width="320" height="320"><source src="figs/wolff_ising_zerofield.webm" type="video/webm"></video>
]

---

  ![scooped](figs/wolff-scoop_title.png)

---

  ![scoop details](figs/wolff-scoop_explanation.png)

---

class: split-40

.column[

# Applying an *arbitrary* field

  Introduce an extra &ldquo;spin&rdquo; `\(r_0\in R\)` whose possible configurations come from the set of *rotations*, not the set of spin states.

  Mark this spin a neighbor of every spin on the lattice.

  New effective coupling defined by
  `\[
    \tilde Z(s,t)=
    \begin{cases}
      Z(s,t) & \text{if $s,t\in X$}\\
      H(t^{-1}\cdot s) & \text{if $t\in R$}\\
      H(s^{-1}\cdot t) & \text{if $s\in R$}
    \end{cases}
  \]`

  Preform ordinary Wolff algorithm on the extended phase space.

  Exact correspondence between expectation values of operators in old and new
  models: if `\(A(\{s\})\)` is an observable on old model in field, `\(\tilde
  A(r_0,\{s\})=A(\{r_0^{-1}\cdot s\})\)` has the property
  `\[
    \langle\tilde
    A\rangle=\mathop{\mathrm{Tr}}\nolimits_{r_0\in R}\mathop{\mathrm{Tr}}\nolimits_{\{s\}\in X^N}\tilde
    A(r_0,\{s\})=\mathop{\mathrm{Tr}}\nolimits_{\{s\}\in X^N}A(\{s\})=\langle A\rangle
  \]`

  ]

  .column[
<video width="320" height="640" style="float:right;"><source src="figs/wolff_ising_field.webm" type="video/webm"></video>
]

---

# Why is the extended method useful?

<img src="figs/vector-1.svg" alt="order-n" style="float: left;"/>
<img src="figs/vector-2.svg" alt="order-n" style="float: right;"/>
<span style="font-size: 30pt; overflow: hidden; height: 7em; text-align: center; align-items: center; display: inline-flex; position: static; float: center">&nbsp;&nbsp;`\[\xrightarrow{r\in O(2)}\]`</span>

---

class: split-40

.column[

# Example: Clock Potts

Consider the clock Potts model with field
`\[
H(m)=0.01\times\begin{cases}
0 & \text{if $m=0$ (black)}\\
\cos(2\pi/6) & \text{if $m=1$ (grey}\\
-\cos(2\pi/6) & \text{if $m=2$ (white)}
\end{cases}
\]`

<img src="figs/potts.svg" style="width:300px;"/>

No rotation `\(r\in\mathbb Z/3\mathbb Z\)` that takes field to the identity!
]
  .column[
<video width="320" height="640" style="float:right;"><source src="figs/wolff_potts_field.webm" type="video/webm"></video>
]

---

# Correlation time scaling

Correlation time scales consistently in the whole phase space!

Pictured: scaling collapses of 2D Ising model correlation time.

<img src="figs/autocorr-scaling-isotherm.png" style="float: left; width: 48%" />
<img src="figs/autocorr-scaling-temp.png" style="float: right; width: 48%" />

---
class: split-50
# Applications &amp; future work
.column[ #### Direct measurements in metastable states

Rapid sampling of states near the critical point of models in a small field occasionally yields microstates against the direction of the field.

<img src="figs/metastable-scaling.png" style="width: 80%; float: left;" />
]

.column[

#### Symmetry-breaking perturbations of XY model

For various values of `\(p\)`, external fields of the form

`\[
H_p(s)=\cos(p\theta(s))
\]`

have various effects on the criticality of the XY model.
]

---

# Questions?

<video><source src="figs/wolff_xy_field.webm" type="video/webm"></video>

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