We study experimentally statistical properties of the opening times of knots in vertically vibrated granular chains. Our measurements are in good qualitative and quantitative agreement with a theoretical model involving three random walks interacting via hard core exclusion in one spatial dimension. In particular, the knot survival probability follows a universal scaling function which is independent of the chain length, with a corresponding diffusive characteristic time scale. Both the large-exit-time and the small-exit-time tails of the distribution are suppressed exponentially, and the corresponding decay coefficients are in excellent agreement with the theoretical values.PACS: 81.05.Rm, 83.10Nn Topological constraints such as knots [1] and entanglements strongly affect the dynamics of filamentary objects including polymers [2][3][4][5] and DNA molecules [6,7]. Typically, large time scales are associated with the relaxation of such constraints [8,9]. Understanding the physical mechanisms governing the relaxation of such constraints is crucial to characterizing flow, deformation, as well as structural properties of materials consisting of ensembles of macromolecules, e.g., polymers, gels, and rubber.Scaling techniques, such as de Gennes-Edwards reptation theory, provide a powerful tool for modeling dynamics of topological constraints [8,9]. These are successful when the precise details of the interparticle interactions are secondary relative to the geometric effects. However, topological constraints are difficult to control experimentally and typically, they can be probed only using indirect methods. Here, we introduce a physical system where these difficulties are greatly reduced, thereby enabling a detailed quantitative comparison with theory. In this Letter, we study dynamics of knots in vibrated granular chains. This system has an appealing simplicity as the "molecular weight" of the chain and the driving conditions can be well controlled. Additionally, the topological constraints can be directly observed. We restrict our attention to simple knots and investigate the time it takes for a knot to open. We find that the average unknotting time τ is consistent with a diffusive behavior τ ∼ N 2 where N is the number of beads in the chain. We also show that statistical properties of opening times are well described by a one dimensional model where three random walks, representing the three exclusion points governing the knot, interact via excluded volume interactions. This model provides an excellent approximation to the knot survival probability. Furthermore, quantitative predictions of this model including fluctuations in the exit times, as well as the coefficients governing the exponential decay of the extremal tails of the distribution are in excellent agreement with the measured values.In the experiments, a simple knot was tightly tied in the center of a ball chain and placed onto a vibrating plate. In Fig. 1, we show images representative of the unknotting process starting from a tightly knotted chain,...
