Revision as of 14:54, 11 February 2024

Goal : final lecture on KPZ and directed polymers at finite dimension. We will show that for $d > 2$ a "glass transition" takes place.

KPZ : from $d = 1$ to the Cayley tree

We know a lot about KPZ, but still we have much to understand:

In $d = 1$ we found $θ = 1 / 3$ and a glassy regime present at all temperatures. The stationary solution of the KPZ equation describes, at long times, the fluctions of quantities like

 $E_{\min} [x] - E_{\min} [x^{'}]$ . However it does not identify the actual distribution of  $E_{\min}$   for a given  $x$ . In particular we have no idea from where Tracy Widom comes from.

In $d > 1$ the exponents are not known. There is an exact solution for the Cayley tree (infinite dimension) that predicts a freezing transition to an 1RSB phase ( $θ = 0$ ).

Let's do replica!

To make progress in disordered systems we have to go through the moments of the partition function. For simplicity we consider polymers starting in $x_{0} = 0$ and ending in $x_{t}$ . We recall that

$V (x, τ)$ is a Gaussian field with

\overline{V (x, τ)} = 0, \overline{V (x, τ) V (x^{'}, τ^{'})} = D δ^{d} (x - x^{'}) δ (τ - τ^{'})

From the Wick theorem, for a generic Gaussian $W$ field we have

\overline{\exp (W)} = \exp [\overline{W} + \frac{1}{2} (\overline{W^{2}} - \overset{2}{\overline{W}})]

The first moment of the partition function is

\overline{Z_{t} [x_{t}, t]} = \int_{x (0) = 0}^{x (t) = x_{t}} 𝒟 x_{1} \exp [- \frac{1}{T} \int_{0}^{t} d τ \frac{1}{2} (\partial_{τ} x)^{2}] \overline{\exp [- \frac{1}{T} \int d τ V (x, τ)]}

Note that the term $T^{2} \overline{W^{2}} = \int d τ_{1} d τ_{2} \overline{V (x, τ_{1}) V (x, τ_{2})} = D t δ_{0}$ has a short distance divergence due to the delta-function. Hence we can write:

\overline{Z_{t} [x_{1}]} = \frac{1}{(2 π t T)^{d / 2}} \exp [- \frac{d}{2} \frac{x_{t}^{2}}{t T}] \exp [\frac{D t δ_{0}}{2 T^{2}}]

The second moment

Step 1:

\overline{Z [x_{t}, t]^{2}} = \exp [\frac{D t δ_{0}}{T^{2}}] \int 𝒟 x_{1} \int 𝒟 x_{2} \exp [- \int_{0}^{t} d τ \frac{1}{2 T} [(\partial_{τ} x_{1})^{2} + (\partial_{τ} x_{2})^{2} - \frac{D}{T^{2}} δ^{d} [x_{1} (τ) - x_{2} (τ)]]

Now you can change coordinate $X = (x_{1} + x_{2}) / 2; u = x_{1} - x_{2}$ and get:

\overline{Z [x_{t}, t]^{2}} = (\overline{Z [x_{t}, t]})^{2} \frac{\int_{u (0) = 0}^{u (t) = 0} 𝒟 u \exp [- \int_{0}^{t} d τ \frac{1}{4 T} (\partial_{τ} u)^{2} - \frac{D}{T^{2}} δ^{d} [u (τ)]]}{\int_{u (0) = 0}^{u (t) = 0} 𝒟 u \exp [- \int_{0}^{t} d τ \frac{1}{4 T} (\partial_{τ} u)^{2}]}

Step 2: Hence, the quantity $\overline{Z [x_{t}, t]^{2}} / (\overline{Z [x_{t}, t]})^{2}$ can be computed.

from the spectrum of the following Hamiltonian

H = - 2 T \nabla^{2} - \frac{D}{T^{2}} δ^{d} [u]

@@ Line 6: / Line 6: @@
 We know a lot about KPZ, but still we have much to understand:
-* In  <math>d=1</math> we found <math>\theta=1/3</math> and a glassy regime present at all temperatures. Moreover, the stationary solution tell us that <math>E_{\min}[x]</math> is a Brownian motion in <math>x</math>. However this solution does not identify the actual distribution of <math> E_{\min}</math>  for a given <math>x</math>. In particular we have no idea from where Tracy Widom comes from.
+* In  <math>d=1</math> we found <math>\theta=1/3</math> and a glassy regime present at all temperatures. The stationary solution of the KPZ equation describes, at long times, the fluctions of quantities like
+ <math>E_{\min}[x]  - E_{\min}[x']</math>. However it does not identify the actual distribution of <math> E_{\min}</math>  for a given <math>x</math>. In particular we have no idea from where Tracy Widom comes from.
 * In <math>d>1</math> the exponents are not known. There is an exact solution for the Cayley tree (infinite dimension) that predicts a freezing transition to an 1RSB phase (<math>\theta=0</math>).
@@ Line 29: / Line 30: @@
 </math></center>
-== Exercise L4-A: the second moment ==
+== The second moment ==
 * Step 1:
 <center> <math>
@@ Line 39: / Line 40: @@
 </math></center>
 * Step 2: Hence, the quantity <math>
-\overline{Z[x_t,t]^2}/ (\overline{Z[x_t,t]})^2</math> can be computed from the spectrum of the following Hamiltonian
+\overline{Z[x_t,t]^2}/ (\overline{Z[x_t,t]})^2</math> can be computed.
+ from the spectrum of the following Hamiltonian
 <center> <math>
 H= -2 T \nabla^2 - \frac{D}{T^2} \delta^d[u]
 </math></center>

L-4: Difference between revisions

Revision as of 14:54, 11 February 2024

KPZ : from $d = 1$ to the Cayley tree

Let's do replica!

The second moment

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L-4: Difference between revisions

Revision as of 14:54, 11 February 2024

KPZ : from d=1 to the Cayley tree

Let's do replica!

The second moment

Navigation menu

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KPZ : from $d = 1$ to the Cayley tree