On the nanostructure of polymer layers formed by adsorption from binary and ternary solutions on a solid SiO2: a combined adsorption and atomic force microscopy (AFM) study

“…The distribution of the sizes and the shape of the domains depend on the original ratio of the components as is evident from Figure . Three different kinds of domain structures have been observed: island-type structures mostly seen in C > C* films (with the exception of the sample prepared from the PS/PBMA = 2:1 binary solution at high concentration), interpenetrated domain structures for the C < C* regime, which are represented in Figure , and lamella type structures with an alternation of the PS and PBMA domains, which can be found mainly for the 1:1 ratio of the components and have been described in our previous publication 2 Typical morphology of mixed adsorption films (PS/PBMA = 1:3) revealed by AFM for low concentration (a−c) and high concentration (d−f) adsorption regimes.…”

“…It should be mentioned that the adsorbed layers are not uniform in thickness, and therefore, the average values of the thickness are provided in Table . The difference between the thicknesses of the layers can be also related to the effect of incompatibility of the polymer components, which implies that the surface of the adsorbent has a mosaic structure with an alternation of regions formed by each polymer component 8 Dependence of the structural parameters of adsorbed films (the average film thickness and rms roughness) on the ratio of polymer components (PS/PBMA) in a mixed polymer solution. …”

“…In a typical adsorption procedure (case 1 or 2), a piece of cleaned and hydrophilic silicon substrate was put (with the working surface up) on the bottom of a beaker filled with a polymer solution of a desirable concentration and polymer−polymer ratio for 4−6 h to ensure adsorption equilibrium . The substrates were then quickly removed from the solution and allowed to dry naturally in a horizontal position to remove the solvent (case 1), or rinsed with pure solvent to remove polymer chains not tightly attached to the solid surface during adsorption (case 2) . It should be stressed that in case 2 the substrate was transferred from the polymer solution to a beaker with pure solvent instantly (i.e., in such a way that the polymer solution layer trapped in the meniscus has not been dried within this procedure, but only after washing of the adsorbed layer with the pure solvent).…”

Atomic Force and Ultrasonic Force Microscopy Investigation of Adsorbed Layers Formed by Two Incompatible Polymers: Polystyrene and Poly(butyl methacrylate)

“…The distribution of the sizes and the shape of the domains depend on the original ratio of the components as is evident from Figure . Three different kinds of domain structures have been observed: island-type structures mostly seen in C > C* films (with the exception of the sample prepared from the PS/PBMA = 2:1 binary solution at high concentration), interpenetrated domain structures for the C < C* regime, which are represented in Figure , and lamella type structures with an alternation of the PS and PBMA domains, which can be found mainly for the 1:1 ratio of the components and have been described in our previous publication 2 Typical morphology of mixed adsorption films (PS/PBMA = 1:3) revealed by AFM for low concentration (a−c) and high concentration (d−f) adsorption regimes.…”

“…It should be mentioned that the adsorbed layers are not uniform in thickness, and therefore, the average values of the thickness are provided in Table . The difference between the thicknesses of the layers can be also related to the effect of incompatibility of the polymer components, which implies that the surface of the adsorbent has a mosaic structure with an alternation of regions formed by each polymer component 8 Dependence of the structural parameters of adsorbed films (the average film thickness and rms roughness) on the ratio of polymer components (PS/PBMA) in a mixed polymer solution. …”

“…In a typical adsorption procedure (case 1 or 2), a piece of cleaned and hydrophilic silicon substrate was put (with the working surface up) on the bottom of a beaker filled with a polymer solution of a desirable concentration and polymer−polymer ratio for 4−6 h to ensure adsorption equilibrium . The substrates were then quickly removed from the solution and allowed to dry naturally in a horizontal position to remove the solvent (case 1), or rinsed with pure solvent to remove polymer chains not tightly attached to the solid surface during adsorption (case 2) . It should be stressed that in case 2 the substrate was transferred from the polymer solution to a beaker with pure solvent instantly (i.e., in such a way that the polymer solution layer trapped in the meniscus has not been dried within this procedure, but only after washing of the adsorbed layer with the pure solvent).…”

Atomic Force and Ultrasonic Force Microscopy Investigation of Adsorbed Layers Formed by Two Incompatible Polymers: Polystyrene and Poly(butyl methacrylate)

“…The conductivity was evaluated as σ = LI / VA , where L is the distance of the silver electrodes, I the measured current, V the applied potential difference and A the cross‐sectional area of the sample, which was calculated as the film thickness multiplied by the width of the film. Polymer film thicknesses were measured using AFM in accordance with a previously described routine19 and their lateral dimensions were measured using a calibrated optical microscope with Image Analyzer software.…”

Synthesis and characterization of polyaniline derivative and silver nanoparticle composites

“…21 From another aspect, a competitive adsorption of the blends of non-interacting (immiscible) polymers on the solid/liquid interfaces was studied. 22,23 Based on a profound analogy between both the processes of macromolecular connection in solutions and of polymer adsorption on a solid/liquid interface, our group has begun for the first time the detailed investigations of competitive interactions in ternary polymer-colloidal systems containing hydrogen bonded Inter-or IntraPC and also mono-or polydispersed colloidal particles. One of the driving forces of these investigations was to explain the effect of a principally higher flocculating capability of both types of polycomplexes compared to individual components and some known flocculating agents, that was established in two real polydispersed colloidal systems such as kaolinite clay/water and coagulant (aluminum sulfate)/natural water suspensions.…”

Inter- And Intramolecular Polycomplexes in Polydispersed Colloidal Systems