Dhagash Mehta, Ciaran Hughes, Michael Kastner, David J Wales
Published 2014-12-10Version 1
The application of numerical techniques to the study of energy landscapes of large systems relies on sufficient sampling of the stationary points. Since the number of stationary points is believed to grow exponentially with system size, we can only sample a small fraction. We investigate the interplay between this restricted sample size and the physical features of the potential energy landscape for the two-dimensional $XY$ model in the absence of disorder with up to $N=100$ spins. Using an eigenvector-following technique, we numerically compute stationary points with a given Hessian index $I$ for all possible values of $I$. We investigate the number of stationary points, their energy and index distributions, and other related quantities, with particular focus on the scaling with $N$. The results are used to test a number of conjectures and approximate analytic results for the general properties of energy landscapes.
Comments: 8 pages, 10 figures. Published in Journal of Chemical Physics
Journal: J. Chem. Phys. 140, 224503 (2014)
Potential Energy Landscapes for the 2D XY Model: Minima, Transition States and Pathways
Thermodynamics of the two-dimensional XY model from functional renormalization
The relationship between fragility, configurational entropy and the potential energy landscape of glass forming liquids
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