Activated carbon oxygen content influence on water and surfactant adsorption

This research investigates the adsorption properties of three activated carbons (AC) derived from coconut, coal, and wood origin. Each carbon demonstrates different levels of resistance to 2 M NaOH treatment. The coconut AC offers the greatest and wood AC the least resistance. The influence of base treatment is mapped in terms of its effects on specific surface area, micropore volume, water adsorption, and dodecanoic acid adsorption from both water and 2 M NaOH solution. A linear relationship exists between the number of water molecules adsorbed at the B-point of the water adsorption isotherm and the oxygen content determined from elemental analysis. Surfactant adsorption isotherms from water and 2 M NaOH indicate that the AC oxygen content effects a greater dependence on affinity for surfactant than specific surface area and micropore volume. We show a linear relationship between the plateau amount of surfactant adsorbed and the AC oxygen content in both water and NaOH phases. The higher the AC oxygen content, the lower the amount of surfactant adsorbed. In contrast, no obvious relationship could be drawn between the surfactant amount adsorbed and the surface area.     

The influence of the preliminary adsorption of water on the adsorption of organic solvent vapors on fullerene materials

The preliminary adsorption of water considerably decreased the sorption capacity of fullerene-containing materials with respect to benzene. The effect grew stronger as the content of fullerenes in the adsorbent increased. The possibility of increasing adsorption capacity by treatment with water was studied. The dependence of the sorption capacity of fullerene materials with respect to benzene on the relative water vapor pressure and the sorption capacity with respect to water at the preadsorption stage was determined.     

Chromatographic properties of open tubular columns with an adsorption layer of aerosil

The chromatographic properties of a porous layer open tubular (PLOT) capillary column with an adsorption layer of highly dispersed silicon dioxide (Aerosil) were studied. It was found that the high efficiency and capacity of the column were retained at high rates of a gas-chromatographic process. The test adsorbent is similar to polydimethyl and polyphenylmethyl siloxane stationary phases in terms of selectivity. Complex multicomponent hydrocarbon mixtures can be separated on the PLOT/SiO₂ column because of low peak asymmetry.     

Surface stoichiometry of zinc sulfide and its effect on the adsorption behaviors of xanthate

ABSTRACT: In this paper, the surface stoichiometry, acid-base properties as well as the adsorption of xanthate at ZnS surfaces were studied by means of potentiometric titration, adsorption and solution speciation modeling. The surface proton binding site was determined by using Gran plot to evaluate the potentiometric titration data. Testing results implied that for stoichiometric surfaces of zinc sulfide, the proton and hydroxide determine the surface charge. For the nonstoichiometric surfaces, the surface charge is controlled by proton, hydroxide, zinc and sulfide ions depending on specific conditions. The xanthate adsorption decreases with increasing solution pH, which indicates an ion exchange reaction at the surfaces. Based on experimental results, the surface protonation, deprotonation, stoichiometry and xanthate adsorption mechanism were discussed.     

Specific cation adsorption on protein-covered particles and its influence on colloidal stability

Protein coated particles present an anomalous colloidal stability at high ionic strength when the classical theory (DLVO) predicts aggregation. This observed deviation from DLVO behaviour appears for electrolyte concentrations above some critical bulk value. As we have suggested in previous publications the existence of an additional short-range repulsive 'hydration force' due to specific hydrated cation adsorption could explain this anomalous stability. The overlap of the hydration layers when two particles approach should provoke this repulsive force. New evidence of this mechanism has been observed when electrophoretic mobilities of protein-carrying latex particles were measured at various concentrations of sodium and calcium chloride. In the latter case a sign reversal of zeta-potential was found, probably due to the specific adsorption of Ca(2+) ions on protein molecules. The adsorption increases with the medium pH. These results have been analyzed following the treatment proposed by Ohshima and co-workers for large charged colloidal particles coated with a layer of protein. This study shows an increase in the positive fixed-charge density on the protein caused by the adsorption of cations.     

The influence of the water content on the adsorption properties of γ-Al2O3

Summary One of the most important parameters which decide the peaks resolution in HPLC with the nonmodified adsorbents, is the amount of water which is present on the adsorbent surface. This article tries to show that the change in the adsorption properties of -Al₂O₃ is dependent on the amount of adsorbed water. These changes are shown with the help of adsorption isotherms, isosteric heats of adsorption and adsorption energy distributions. The data is analysed on the bases of Jovanovic equations. It was also found that a relationship exists between the Brockman activity scale and the adsorption isotherm of water on -Al₂O₃.     

Surface modification of MCM-41 and its application in DNA adsorption

Three types of MCM-41 absorbents, namely, Al~(3+)–MCM-41, La~(3+)–MCM-41, and Zn~(2+)–MCM-41, were prepared through amine grafting, phosphonate modification, and metal ion chelation and characterized by Fourier transform infrared spectroscopy, thermogravimetric analysis, and N2adsorption–desorption analysis. Results revealed that functionalized MCM-41 maintains the original structure of the molecular sieve and that the pore diameter and surface area are reduced compared with those of pure MCM-41. The adsorption behavior of DNA molecules on the surface of the modified molecular sieves was discussed according to the hard-soft acid–base(HSAB) principle. Experimental results showed that DNA purification could be effectively carried out on functionalized MCM-41 and that DNA is easily released by3–4 molL~(-1)NaCl solution. This study could be used as a general platform for future work on DNA adsorption and enrichment.     

Photophysics of pyrene adsorbed on aerosil

The spectral luminescence properties of pyrene adsorbed on the surface of aerosil have been investigated at different thermal activation temperatures (453, 773, and 1073°K) and different degrees of surface coverage (0.01–10% of monolayer). The differences from the properties of pyrene adsorbed on silica gel are dictated by the high polarity of the aerosil surface, the less significant rearrangement of its hydroxyl coverage in thermal treatment, and its pronounced energetic discrete homogeneity at low degrees of coverage.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 23, No. 1, pp. 121–125, January–February, 1987.     

Surface modification of magnetic metal nanoparticles and its influence on the performance of polymer composites

To control the interfacial interaction in magnetic metal nanoparticles‐filled polymer composites, surfaces of iron, cobalt, and nickel nanoparticles were grafted by irradiation‐induced polymerization. On the basis of the study of dynamical mechanical behavior, thermal stability, and magnetic performance of the composites prepared by either solution mixing or in situ polymerization, the structure–property relationships of the composites are a function of interfacial interaction and the dispersion state of the nanoparticles. In addition, grafting of polymers onto the surface of the metal nanoparticles changed the surface magnetic state, leading to the possibility of purposely tailoring the magnetic behavior of the composites. © 2003 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 41: 1070–1084, 2003     

Determination of the concentration of hydroxyl groups on aerosil surfaces

The concentration of the hydroxyl groups on Aerosil surfaces was estimated by chemical analysis and IR spectroscopy. The temperature ranges for thermal stability of the OH groups and for their reactivity in surface chemical reactions were established. Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 10, pp. 1757–1760, October, 1997.     

The influence of solvation on the mechanism of ethylene and benzene methylation

By means of the MINDO/3 method, elcctrophilic attack of CH⁺₃ and CH⁺₃OH⁺₂ on ethylene and benzene has been studied in order to discuss the timing or desolvalion. Partial desolvation at the transition stale is found. The implications of this fact are analyzed.     

Fibronectin adsorption on tantalum: the influence of nanoroughness

The complex mechanisms of protein adsorption at the solid-liquid interface is of great importance in many research areas, including protein purification, biocompatibility of medical implants, biosensing, and biofouling. The protein adsorption process depends crucially on both the nanoscale chemistry and topography of the interface. Here, we investigate the adsorption of the cell-binding protein fibronectin on flat and nanometer scale rough tantalum oxide surfaces using ellipsometry and quartz crystal microbalance with dissipation (QCM-D). On the flat tantalum oxide surfaces, the interfacial protein spreading causes an increase in the rigidity and a decrease in the thickness of the adsorbed fibronectin layer with decreasing bulk protein concentration. For the tantalum oxide surfaces with well-controlled, stochastic nanometer scale roughness, similar concentration effects are observed for the rigidity of the fibronectin layer and saturated fibronectin uptake. However, we find that the nanorough tantalum oxide surfaces promote additional protein conformational changes, an effect especially apparent from the QCM-D signals, interpreted as an additional stiffening of the formed fibronectin layers.     

Ion adsorption and its influence on direct current electric field induced deformations of flexoelectric nematic layers

The influence of ion adsorption on the behavior of the nematic liquid crystal layers is studied numerically. The homeotropic flexoelectric layer subjected to the dc electric field is considered. Selective adsorption of positive ions is assumed. The analysis is based on the free energy formalism for ion adsorption. The distributions of director orientation angle, electric potential, and ion concentrations are calculated by numerical resolving of suitable torques equations and Poisson equation. The threshold voltages for the deformations are also determined. It was shown that adsorption affects the distributions of both cations and anions. Sufficiently large number of adsorbed ions leads to spontaneous deformation arising without any threshold if the total number of ions creates sufficiently strong electric field with significant field gradients in the neighborhood of electrodes. The spontaneous deformations are favored by strong flexoelectricity, large thickness, large ion concentrations, weak anchoring, and large adsorption energy.