P. H. Lundow
Published 2021-03-15Version 1
High-dimensional ($d\ge 5$) Ising systems have mean-field critical exponents. However, at the critical temperature the finite-size scaling of the susceptibility $\chi$ depends on the boundary conditions. A system with periodic boundary conditions then has $\chi\propto L^{5/2}$. Deleting the $5L^4$ boundary edges we receive a system with free boundary conditions and now $\chi\propto L^2$. In the present work we find that deleting the $L^4$ boundary edges along just one direction is enough to have the scaling $\chi\propto L^2$. It also appears that deleting $L^3$ boundary edges results in an intermediate scaling, here estimated to $\chi\propto L^{2.275}$. We also study how the energy and magnetisation distributions change when deleting boundary edges.
Comments: 7 pages, 16 figures
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