A preaveraged topological parameter, TV, is introduced to provide a criterion for the presence of entanglements in polymer melts. The theory predicts a geometrical transition from the entangled to the unentangled state in agreement with experimental data. A generalized Rouse theory is used to describe polymer dynamics in both states.PACS numbers: 61.41.+e, 36.20.Ey, 62.10.+S In the reptation model for entangled polymers, 1,2 a polymer diffuses in a dense network of entanglements formed by the surrounding chains. The model assumes that the entanglements are sufficiently long-lived that diffusional motion is essentially one dimensional in a confining tube. The detailed conformation of the polymer chain is replaced by a connected sequence of freely jointed links corresponding to equal-sized segments of polymer, whose length is equal to the mean number of monomers between entanglements, N e , which then evolves in a stochastic earthworm fashion creating and destroying the tube at the ends. The phenomenological parameter N e is assumed to be a property of the entangled chains and independent of the chain length. A direct calculation of N e , for a particular system, has not been accomplished because of the difficulty of topological classification of entanglements. In practice, N e is used as an experimental fitting parameter.In this paper, we introduce a reformulation of the tube Ansatz. The parameter N e is replaced by a new parameter, TV, called the coordination number, whose value is expected to be universal. In the present theory, TV is a geometrical property of the entangling chains and can be related to N e and TV r , the critical chain size for the presence of long-lived entanglements. Polymer dynamics, in the entangled state, can then be described by a suitable projection of the Rouse equation onto a tube axis. Several scaling properties of polymer melts and concentrated solutions followed directly from this theory.Our system of interest consists of Gaussian monodisperse chains with TV skeletal bonds, bond length /, and bond number density p m . Focusing on one chain, hereafter called the test chain, we inscribe a subsection of the chain, with N e bonds, in a sphere of diameter A^1 /2 /, i.e., the mean distance spanned by the N e bonds (see Fig. 1). For the moment N e will be some arbitrary number less than TV. In a high-density system, several other polymers will thread through this sphere and may be involved in forming entanglements with the test chain segment, or may restrict the lateral degrees of freedom of the chain. With the help of Fig. 1 we can see that the probability of this situation occurring is not independent of chain lengths. For example, if we rescale all polymer lengths according to TV-* N/2 by simply cutting all polymers at their midpoints (Fig. 1, lower part), some of our scissions will occur within the test sphere. The new polymer ends produced by this cutting will lessen the probability of forming entanglements or having lateral constraints, and increase the mean spacing between entang...
