An extensive effort to characterize polystyrenes of a wide range of molecular weights of up to M, = 40 X lo6 by a variety of different methods is reported. The employed methods of investigation, such as frequency analyzing (dynamic) and frequency averaging (classical) light scattering, velocity sedimentation, and viscometry, always lead to linear double-logarithmic relationships between the obtained quantities and the molecular weight. Molecular weight distributions of several samples in the same molecular weight range were investigated as well by classical light scattering, velocity sedimentation, and GPC. Comparison of the results, also with fractionation data, gives good agreement between the different methods and demonstrates the usefulness of some new approaches.Until recently, synthetic polymers of extremely high molecular weights have only been of limited interest to the scientific world, even though an extension of the molecular weight scale by one or two decades might provide a crucial experimental test for some theoretical equations, e.g., relating the conformation to the excluded volume.There are, however, a number of problems associated with the investigation of the properties of extremely high molecular weight polymers: For one, the systematic preparation of such polymers requires in general a rather refined experimental technique which must meet the most stringent purity specifications, irrespective of the mode of synthesis. Anionic polymerization has been advanced systematically to yield polystyrenes in the molecular weight range of M , = 13 X lo6 with narrow molecular weight distributions (MWD).' Earlier, McIntyre et ala2 had been successful in obtaining an anionic polystyrene of M , = 44 X lo6. Emulsion polymerization just recently yielded a polystyrene of M , = 57 X lo6 after fra~tionation.~ Purely thermal polymerization of styrene at low temperatures to low conversion leads to polymers of similarly high molecular weights ( M , = 35 X lo6 ~nfractionated).~ Spontaneous thermal polymerization of methyl methacrylate at lower temperatures produces polymers in the same or possibly higher molecular weight range.5 The latter two modes of polymerization yield molecular weight distributions of M,/M,, = 2, since their molecular weights are regulated by transfer reactions to an intermediate and/or the monomer, respectively.
