Structure-rheology relationship in weakly amphiphilic block-copolymer Langmuir monolayers

The linear viscoelastic behaviour in the low-frequency regime at the water/ air interface of three different polystyrene-b-poly-methylmetacrylate (PS-b-PMMA) copolymer monolayers, with block length ratio varying from 66-33, to 50-50 and 25-75 in molecular units, was studied and related to the interfacial behaviour, characterized by means of Langmuir isotherms, and their structure, characterized by means of Atomic Force Microscopy technique. The two monolayers with the highest PMMA amount showed a single phase transition at about 12 mN/m, the viscoelastic behaviour changing from a predominantly elastic to a viscoelastic one. This change in the viscoelastic properties was ascribed to the beginning of entanglement among the PMMA coronas of the predominantly circular quasi-2D micelles formed by the two copolymer systems. Conversely the polymer with the lowest PMMA amount, despite having the same PMMA block length of the PS-PMMA 50-50 block copolymer, was found to behave as a viscoelastic system at any surface pressure value. This characteristic behavior cannot therefore be simply related to the molecular weight difference but it has been put in connection to the irregular micelle structure observed in this case, consisting of a mixture of spherical and worm-like micelles, and to the different conformation adopted by the PMMA block. By blending this copolymer with an immiscible elastic homopolymer, namely poly-2-vinylpyridine, it was possible to tune the micelle nano-structure, obtaining regular circular quasi-2D micelles, with viscoelastic properties as expected for the PMMA–rich copolymer monolayers. To the best of our knowledge this study shows for the first time the explicit dependence upon the relative block length and, in turn, upon the nanostructure of the quasi-2D micelles, of the viscoelastic properties of Langmuir monolayers and suggests that molecular weight and intermolecular interactions are not the only parameters governing the polymer conformation and, in turn, the polymer rheology and dynamics in quasi-2D confined systems.