Exact Solutions for Loewner Evolutions
Abstract
In this note, we solve the Loewner equation in the upper half-plane with forcing function xi(t), for the cases in which xi(t) has a power-law dependence on time with powers 0, 1/2 and 1. In the first case the trace of singularities is a line perpendicular to the real axis. In the second case the trace of singularities can do three things. If xi(t)=2*(kappa*t)^1/2, the trace is a straight line set at an angle to the real axis. If xi(t)=2*(kappa*(1-t))^1/2, the behavior of the trace as t approaches 1 depends on the coefficient kappa. Our calculations give an explicit solution in which for kappa<4 the trace spirals into a point in the upper half-plane, while for kappa>4 it intersects the real axis. We also show that for kappa=9/2 the trace becomes a half-circle. The third case with forcing xi(t)=t gives a trace that moves outward to infinity, but stays within fixed distance from the real axis. We also solve explicitly a more general version of the evolution equation, in which xi(t) is a superposition of the values +1 and -1.
Cite
@article{arxiv.math-ph/0309006,
title = {Exact Solutions for Loewner Evolutions},
author = {Wouter Kager and Bernard Nienhuis and Leo P. Kadanoff},
journal= {arXiv preprint arXiv:math-ph/0309006},
year = {2007}
}
Comments
20 pages, 7 figures, LaTeX, one minor correction, and improved hyperrefs