Adsorption of Hydrophobically Modified Poly(acrylic acid) Sodium Salt at the Air/Water Interface by Combined Surface Tension and X-ray Reflectivity Measurements

Abstract: The adsorption at the air/water interface of hydrophobically modified poly(acrylic acid) sodium salt (HMPAANa) with various degrees of grafting and lengths of graft has been investigated using both tensiometry and X-ray reflectivity techniques. Tensiometry has provided the Gibbs adsorption isotherms and has revealed that HMPAANa associating copolymers behave like low molecular weight surfactants with surface tensions leveling off at the critical aggregate concentrations (cac) determined from viscosity measurem… Show more

“…The similar behavior, i.e. the existence of the lag-time and the long relaxation time (sometimes ∼10 6 s) for the surface and interfacial tension, was reported for hydrophobically modified polymers and proteins, which unfold at the interface and may adsorb irreversibly by "anchoring" their multiple hydrophobic functional groups into the non-polar phase [6][7][8][9][10][11][12]. The decrease of the interfacial tension during so long time signifies that this decrease is controlled not only by the diffusion of macromolecules from the bulk to the interface and their adsorption but mainly by the diffusion of surface active segments of the already adsorbed macromolecules via their reconformation inside the adsorption layer.…”

“…The decrease of the interfacial tension during so long time signifies that this decrease is controlled not only by the diffusion of macromolecules from the bulk to the interface and their adsorption but mainly by the diffusion of surface active segments of the already adsorbed macromolecules via their reconformation inside the adsorption layer. The phase transition phenomena (collapse, aggregation, gellation) inside the adsorption layers may oc- cur as well in the course of the ageing of the adsorption layers and under compression [9,10]. Unlike the water-soluble polymers and proteins, which adsorb at the oil-water interface by their hydrophobic moieties (Fig.…”

Adsorption kinetics of hydrophobic polysoaps at the methylene chloride–water interface

“…The similar behavior, i.e. the existence of the lag-time and the long relaxation time (sometimes ∼10 6 s) for the surface and interfacial tension, was reported for hydrophobically modified polymers and proteins, which unfold at the interface and may adsorb irreversibly by "anchoring" their multiple hydrophobic functional groups into the non-polar phase [6][7][8][9][10][11][12]. The decrease of the interfacial tension during so long time signifies that this decrease is controlled not only by the diffusion of macromolecules from the bulk to the interface and their adsorption but mainly by the diffusion of surface active segments of the already adsorbed macromolecules via their reconformation inside the adsorption layer.…”

“…The decrease of the interfacial tension during so long time signifies that this decrease is controlled not only by the diffusion of macromolecules from the bulk to the interface and their adsorption but mainly by the diffusion of surface active segments of the already adsorbed macromolecules via their reconformation inside the adsorption layer. The phase transition phenomena (collapse, aggregation, gellation) inside the adsorption layers may oc- cur as well in the course of the ageing of the adsorption layers and under compression [9,10]. Unlike the water-soluble polymers and proteins, which adsorb at the oil-water interface by their hydrophobic moieties (Fig.…”

Adsorption kinetics of hydrophobic polysoaps at the methylene chloride–water interface

“…However, at increasing polymer concentrations, a singular increase in σ values was clearly observed, particularly with the DexP 15 and DexP 22 derivatives. Similar behaviors were obtained with hydroxypropyl methylcellulose (6) or short polyoxyethylene dodecyl ether (19). This could be explained by a change in the polymer conformation at the interface but further investigations are necessary to clarify this point.…”

“…Since these values are much lower than those found for C * , the question was then "is the polymer aggregation in the aqueous phase really related to the CC values?" Differences between C * and CC values can be explained as follows: at CC, a dense and viscoelastic DexP layer is formed at the air-water interface, with no possible diffusive exchange with the bulk phase since the polymer, having much more than one phenoxy anchoring group per chain, is quite irreversibly adsorbed at the interface (19)(20)(21). Thus, further increases in the bulk concentration do not cause any more adsorption and the surface tension remains constant, even in the absence of large polymeric aggregates in the solution.…”

Surface Activity and Emulsification Properties of Hydrophobically Modified Dextrans

“…수분을 흡착하는 역할을 한다 [12]. 이 PASS은 무독성 물질로 수분과 직접 접촉으로 빠르게 수분을 흡수하여 위생용품, 의료용, 그리고 산 업용 실링재 등 상용화 소재로 사용되고 있다 [13].…”

Preparation and Properties of Moisture-absorbing Film Impregnated with Polyacrylic Acid Partial Sodium Salt Material