Geometry, Topology, and Universality of Random Surfaces
- 10 May 1991
- journal article
- other
- Published by American Association for the Advancement of Science (AAAS) in Science
- Vol. 252 (5007) , 825-827
- https://doi.org/10.1126/science.252.5007.825
Abstract
Previous simulations of a self-avoiding, closed random surface with restricted topology (without handles) on a three-dimensional lattice have shown that its behavior on long length scales is consistent with that of a branched-polymer. It is shown analytically that such a surface with an unrestricted number of handles has a qualitatively different geometry and therefore is in a different universality class. The effect of a net external pressure is to suppress the handles and collapse the surface into a branched polymer-like configuration. Topology is thus shown to be a key factor in determining the universality class of the system.Keywords
This publication has 16 references indexed in Scilit:
- Critical behavior of two-dimensional vesicles in the deflated regimePhysical Review A, 1991
- Diffraction from Polymerized MembranesScience, 1990
- Tunable fractal shapes in self-avoiding polygons and planar vesiclesPhysical Review Letters, 1990
- Monte Carlo study of self-avoiding surfacesJournal of Statistical Physics, 1988
- Thermodynamic behavior of two-dimensional vesiclesPhysical Review Letters, 1987
- On the universality class of planar self-avoiding surfaces with fixed boundaryJournal of Physics A: General Physics, 1987
- Scaling Behavior of Self-Avoiding Random SurfacesPhysical Review Letters, 1984
- The number of random surfaces on the lattice and the large-N gauge theoryPhysics Letters B, 1982
- Critical Behavior of Branched Polymers and the Lee-Yang Edge SingularityPhysical Review Letters, 1981
- The application of renormalization group techniques to quarks and stringsReviews of Modern Physics, 1977