Random Walks and the Correlation Length Critical Exponent in Scalar Quantum Field Theory
arXiv:hep-lat/9202002
Abstract
The distance scale for a quantum field theory is the correlation length $ξ$, which diverges with exponent $ν$ as the bare mass approaches a critical value. If $t=m^{2}-m_{c}^{2}$, then $ξ=m_{P}^{-1} \sim t^{-ν}$ as $t \to 0$. The two-point function of a scalar field has a random walk representation. The walk takes place in a background of fluctuations (closed walks) of the field itself. We describe the connection between properties of the walk and of the two-point function. Using the known behavior of the two point function, we deduce that the dimension of the walk is $d_{w}=Ï/ ν$ and that there is a singular relation between $t$ and the energy per unit length of the walk $θ\sim t^Ï$ that is due to the singular behavior of the background at $t=0$. ($Ï$ is a computable crossover exponent.)