Anomalous finite-size effects and canonical asymptotic behaviors for the mean-squared gyration radius of Gaussian random knots
Abstract
Anomalously strong finite-size effects have been observed for the mean square radius of gyration R2K of Gaussian random polygons with a fixed knot K as a function of the number N of polygonal nodes. Through computer simulations with N < 2000, we find for several knots that the gyration radius R2K can be approximated by a power law: R2K N2 Keff, where the effective exponents Keff for the knots are larger than 0.5 and less than 0.6. A crossover occurs for the gyration radius of the trivial knot, when N is roughly equal to the characteristic length Nc of random knotting. For the asymptotic behavior of R2K, however, we find that it is consistent with the standard one with the scaling exponent 0.5. Thus, although the strong finite-size effects of R2K remain effective for extremely large values of N, they can be matched with the asymptotic behavior of random walks.
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