Andreas Winter

Supramolecular Polymers and Assemblies


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of monomers by equilibrium bond formation and features an ideal polymerization temperature (Tp0) [50–54]. The Dainton–Ivin equation, initially introduced to describe the thermodynamics of ROP and polyaddition reactions, correlates the enthalpy and entropy of propagation (ΔHpr and ΔSpr) as well as the initial monomer mole fraction to Tp0 (Eq. (1.3)) [55, 56]. There are two fundamental cases that one must distinguish:

      1 The polymerization only occurs at a temperature so high that the entropy term exceeds the enthalpy term and the system exhibits a floor temperature (ΔHpr, ΔSpr > 0).

      2 The polymerization represents an enthalpically driven process, which is only allowed below a certain ceiling temperature (ΔHpr, ΔSpr < 0).

      The so‐called polymerization transition line, separating monomer‐rich phases from polymer‐rich ones, can be constructed by plotting [Mi] vs. the polymerization temperature, which can be determined experimentally. However, this model is only valid in those cases where a sharp monomer‐to‐polymer transition can be found (in general, applicable only for ring‐opening, living, or cooperative polymerizations) [50]. For most of the reported IDPs, this transition is, however, very broad and the two phases rather coexist. Thus, for such a supramolecular polymerization, the polymerization transition line as a boundary appears less appropriate.

      where Tp0: ideal polymerization temperature, ΔHpr: enthalpy of propagation, ΔSpr: entropy of propagation, R: gas constant, [Mi]: initial mole fraction of a monomer.

      Source: van der Schoot et al. [57]. © 2005 Taylor & Francis.

      Source: Modified from Dudowicz et al. [50]; Douglas et al. [51].