L-4: Difference between revisions
Jump to navigation
Jump to search
| Line 20: | Line 20: | ||
The first moment of the partition function is | The first moment of the partition function is | ||
<center> <math> | <center> <math> | ||
\overline{Z_t[x_1] } =\int {\cal D} x_1 \exp\left[- \frac{1}{ | \overline{Z_t[x_1] } =\int {\cal D} x_1 \exp\left[- \frac{1}{T} \int_0^t d \tau (\partial_\tau x)^2\right] \overline{\exp\left[- \frac{1}{T} \int d \tau V(x,\tau ) \right]} | ||
</math></center> | </math></center> | ||
Note that the term <math>\overline{W^2} =\int d \tau_1 d\tau_2 \overline{V(x,\tau_1}V(x,\tau_2}= D t \delta(0)</math> has a short distance divergence due to the delta-functiton, but is path independent. Hence we can write: | |||
<center> <math> | <center> <math> | ||
ciao | |||
</math></center> | </math></center> | ||
<center> <math> | <center> <math> | ||
\overline{Z_t[x_1] Z_t[x_2]} =\int {\cal D} x_1\int {\cal D} x_2 \exp\left[- \frac{1}{2T} \int_0^t d \tau [(\partial_\tau x_1)^2+ (\partial_\tau x_2)^2 \right] \int_0^t \int_0^t d \tau_1 d \tau_2 \overline{\exp\left[- \frac{V(x_1(\tau_1)) V(x_2(\tau_2)) }{T}\right]} | \overline{Z_t[x_1] Z_t[x_2]} =\int {\cal D} x_1\int {\cal D} x_2 \exp\left[- \frac{1}{2T} \int_0^t d \tau [(\partial_\tau x_1)^2+ (\partial_\tau x_2)^2 \right] \int_0^t \int_0^t d \tau_1 d \tau_2 \overline{\exp\left[- \frac{V(x_1(\tau_1)) V(x_2(\tau_2)) }{T}\right]} | ||
Revision as of 00:34, 5 January 2024
Goal 1: final lecture on KPZ and directed polymers at finite dimension. We will show that for a "glass transition" takes place.
Goal 2: We will mention some ideas related to glass transition in true glasses.
Part 1: KPZ in finite dimension
- In we found and a glassy regime present at all temperatures. Moreover, the stationary solution tell us that is a Brownian motion in . However this solution does not identify the actual distribution of for a given . In particular we have no idea from where Tracy Widom comes from.
![{\displaystyle E_{\min }[x]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/c066b9d27e99b30b243587508ec15d396314ca63)
- In the exponents are not known. There is an exact solution for the Caley tree (infinite dimension) that predicts a freezing transition to an 1RSB phase ().
Let's do replica!
To make progress in disordered systems we have to go through the moments of the partition function. We recall that
- is a Gaussian field with
- From the Wick theorem, for a generic Gaussian field we have
\overline{e^W}= e^{\overline{W} +\frac{1}{2} (\overline{W^2}-\overline{W}^2)}
The first moment of the partition function is
![{\displaystyle {\overline {Z_{t}[x_{1}]}}=\int {\cal {D}}x_{1}\exp \left[-{\frac {1}{T}}\int _{0}^{t}d\tau (\partial _{\tau }x)^{2}\right]{\overline {\exp \left[-{\frac {1}{T}}\int d\tau V(x,\tau )\right]}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/71d0459ba05e70e27e64e96b3c676c9b5fbdbaf7)
Note that the term Failed to parse (syntax error): {\displaystyle \overline{W^2} =\int d \tau_1 d\tau_2 \overline{V(x,\tau_1}V(x,\tau_2}= D t \delta(0)} has a short distance divergence due to the delta-functiton, but is path independent. Hence we can write:
![{\displaystyle {\overline {Z_{t}[x_{1}]Z_{t}[x_{2}]}}=\int {\cal {D}}x_{1}\int {\cal {D}}x_{2}\exp \left[-{\frac {1}{2T}}\int _{0}^{t}d\tau [(\partial _{\tau }x_{1})^{2}+(\partial _{\tau }x_{2})^{2}\right]\int _{0}^{t}\int _{0}^{t}d\tau _{1}d\tau _{2}{\overline {\exp \left[-{\frac {V(x_{1}(\tau _{1}))V(x_{2}(\tau _{2}))}{T}}\right]}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/80e28caccbbf2c0b2bf45153eb24d4ec762c26ec)