Ionic amphiphilic diblock copolymers, such as polystyreneb-poly(styrenesulfonate), show non-surface activity when some requirements are satisfied. The main origin of this unique property has been thought to be an image charge repulsion at the air/water interface. In this study, surface activity/non-activity was examined for random copolymers in addition to homopolymers. Random copolymers of styrene and styrenesulfonate were found to be surface active, while the poly(styrenesulfonate) homopolymer was slightly surface active. This observation cannot be interpreted by image charge repulsion alone since these are all polyanions and the block copolymer is mostly hydrophobic. Stable polymer micelle formation in the block copolymer system is also an essential origin of non-surface activity.Ionic amphiphilic diblock copolymers, which consist of hydrophobic and ionic blocks, show non-surface activity under suitable conditions.19 Their aqueous solutions show no or little reduction of surface tension and foam formation, while a multimolecular micelle is formed in the bulk solution. This phenomenon is, in a sense, out of common sense of surface and interface science since the micelle has been believed to be formed by the "surfactant (surface active agent)" above the critical micelle concentration (cmc). We have systematically investigated this unique property for strongly 1,2,4,5 and weakly 3 anionic amphiphilic block copolymers and also cationic 6,7 block copolymers. As a result, we have proposed an image charge effect 1014 at the air/water interface as the first essential origin of this phenomenon. Since the hydrophilic segment is a polyelectrolyte, which has many charges, the block copolymer adsorbed at the air/water interface by a hydrophobic effect is destabilized by strong image charge repulsion from the water surface. When salt was added into the solution, the polymers changed to be surface active; the surface tension of the solution decreased and showed foam formation activity. From this result, it is obvious that the electrostatic effect plays an important role in the origin of non-surface activity.4 Also, when the hydrophobic block becomes long enough compared to the length of the hydrophilic, ionic block, the polymer shows surface activity. The hydrophobic adsorption effect might be stronger than the image charge repulsion. Also, the total length (molecular weight) should be long enough to be surface active. Chen et al. reported that the polymer with a block length of m:n = 30:30 was non-surface active while m:n = 15:15 polymer showed surface activity.9 In this sense, non-surface activity is some kind of polymer effect. Furthermore, non-surface activity was also observed and has been reported by other researchers for different systems.
1523On the other hand, most polyelectrolyte homopolymers are slightly surface active. 24,25 Sen et al. reported the reduction of surface tension of aqueous poly(styrenesulfonate) (PSS) solutions, 24 and Yim et al. detected the adsorbed poly(syrenesulfonate) potassium salt molecule...
