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We apply renormalization-group and Monte Carlo methods to study the equilibrium conformations and dynamics of two-dimensional surfaces of fixed connectivity embedded in d dimensions, as exemplified by hard spheres tethered together by strings into a triangular net. A continuum description of the surfaces is obtained. Without self-avoidance, the radius of gyration increases as, where L is the linear size of the uncrumpled surface. The upper critical dimension of self-avoiding surfaces is infinite. Their radius of gyration grows as L^, where Flory theory predicts =4/ (d+2), in agreement with our Monte Carlo result =0. 800. 05 in d=3. The Rouse relaxation time of a self-avoiding surface grows as L^3. 6.
Kantor et al. (Wed,) studied this question.