In early 1950s,
Paul J. Flory was the pioneer who developed theories to explain topology within a polymer network, and the structure-property relationships between the topology and the mechanical property, like elasticity, was initially established afterwards. In early 2000s, Yasuyuki Tezuka and coworkers were the first ones that systematically described a single molecular chain with topological information. Adapted from Y. Tezuka and coworker's description of a topological polymer chain with more generalized rules, the topology notation rules are to be introduced first, followed by three classical classifications, including linear, branched and cyclic polymer topologies, and they are classified in a table reorganized and redrawn from Y. Tezuka and coworker (Copyright, 2001 by
American Chemical Society). A general polymer chain could be generalized into an
undirected graph with
nodes (vertices or points) and
edges (lines or links) based on
graph theory. In a graph theory topology, two sets of nodes are present, termini and junctions. The quantity ‘
degree’ represents the number of edges linked to each node, if the degree of a certain node is larger than 3 (including 3), the node is a junction, while the degree of a node is 1, the node is a terminus. There are no nodes with a degree of 2 since they could be generalized into their adjacent nodes. As for a certain polymer, as long as the topology is fixed, a specific topology notation could be generated using the following rules: A general polymer chain notation could be expressed as: P_m(x,y)[s_1(s_{11},s_{12},..),s_2(s_{21},s_{22},...),...] • Capitalized letter P represents the main topology within a polymer, A represents linear or branched topology, and Roman numerals are used to represent the number of rings in the polymer chain, I represents one cycle, II represents two cycles, III, IV, V, etc. represents three, four, five cycles and so on. • m represents the number of nodes in the graph theory topology, x represents the number of termini and y represents the number of junctions, and m=x+y is always true. • If P_m(x,y) could represent an exclusive topology, there is no need to add more information to specify the notation. However, if multiple possibilities are present, extra information is needed. i. For branched topology, a main chain is first selected, and the degree of each junction nodes along the chain should be noted as s_i connected by a hyphen. If there is a
side chain on any of the main chain node, s_{ij} should be noted with a bracket following the main chain notation. ii. For monocyclic topology, the outward branch should be firstly identified with the number of branches at each of the junctions as s_i connected by a hyphen. Then the topology of each branch should be identified using the rule in i as s_{ij} using a bracket following the s_i notations. iii. For multicyclic topology, superscript letter (a, b, c and so on) is used to describe internal connections within an existing ring.
Linear Linear topology is a special topological structure that exclusively has two nodes as the termini without any junction nodes.
High-density polyethylene (HDPE) could be regarded as a linear polymer chain with very small amount of branching, the linear topology has been listed below: Linear chains capable of forming intra-chain interactions can fold into a wide range of
circuit topologies. Examples include biopolymers such as
proteins and
nucleic acids.
Branched When side chains are introduced into a linear polymer chain, a
branched topology forms. Linear polymers are special types of branched polymers with zero junction nodes, but they are cataloged into two classifications to distinguish their special macroscopic properties. Branched polymers with the same molecular weight usually demonstrate different physical properties due to that branching could generally decrease the
van der Waals interactions between each of the polymer chain. Several well-known branched polymers have been synthesized, such as
star-shape polymer,
comb polymer and
dendrimer. Selected branched topologies have been listed below:
Cyclic Cyclic structures are of interest topologically because there are no termini in this topology and the physical property could be dramatically different as a result of the restriction of the termini.
Monocyclic Monocyclic topology is a topological structure with only one cycle in the polymer chain, and it could be coupled with outward branching structures. Selected monocyclic topologies have been listed below:
Bicyclic Bicyclic topology refers to a structure that two cycles connected internally or externally are present in a polymer chain. Selected bicyclic topologies are listed below:
Polycyclic Similar to monocyclic and bicyclic topologies, polycyclic topologies possess more cycles in a polymer chain and are more synthetically challenging. Selected polycyclic (tricyclic) topologies are listed below: == Polymer network topology ==