Sorption of aminonaphthalene and quinoline on amorphous silica

Abstract: The adsorption of quinoline and aminonaphthalene was investigated from aqueous solution on amorphous silica @io2). Amorphous Si02 was not a strong adsorbent of these compounds and quinoline was adsorbed more strongly than aminonaphthalene. The adsorption of both compounds varied with pH. A maximum in adsorption occurred near their respective pK,'s. Temperature effects were significant, suggesting enthalpy contributions in the range of H bonding. Both compounds appeared to adsorb via identical mechanisms that i… Show more

“…For example, Zachara et al [17] found that the adsorption of aminonaphthalene and quinoline onto amorphous silica over the pH range from 3 to 8 decreased as temperature increased. This result is in accord with our study, since the silica surface will be negatively charged over this pH range.…”

“…This small enthalpy change is consistent with the notion that mellitate-substrate bonds are the result of electrostatic and hydrogen bonding interactions (outer-sphere complexation). Zachara et al [17] found that the adsorption of both quinoline and aminonaphthalene to amorphous silica were usually exothermic, but depended on the temperature interval and surface coverage. They also suggested that adsorption was non-specific because the enthalpies spanned the range usually associated with van der Waals and hydrogen bonding.…”

“…Generally current studies have indicated that an increase in temperature is accompanied by a decrease in adsorption [12,[17][18][19][20][21]. In some of these investigations [17,18,20,21] thermodynamic parameters were calculated, and adsorption was shown to be exothermic. Most of these studies, however, dealt with nonpolar adsorbates such as herbicides and pesticides, making it difficult to anticipate the effect of temperature in systems that contain polar molecules such as the benzene carboxylic acids.…”

The influence of temperature on the adsorption of mellitic acid onto goethite

“…For example, Zachara et al [17] found that the adsorption of aminonaphthalene and quinoline onto amorphous silica over the pH range from 3 to 8 decreased as temperature increased. This result is in accord with our study, since the silica surface will be negatively charged over this pH range.…”

“…This small enthalpy change is consistent with the notion that mellitate-substrate bonds are the result of electrostatic and hydrogen bonding interactions (outer-sphere complexation). Zachara et al [17] found that the adsorption of both quinoline and aminonaphthalene to amorphous silica were usually exothermic, but depended on the temperature interval and surface coverage. They also suggested that adsorption was non-specific because the enthalpies spanned the range usually associated with van der Waals and hydrogen bonding.…”

“…Generally current studies have indicated that an increase in temperature is accompanied by a decrease in adsorption [12,[17][18][19][20][21]. In some of these investigations [17,18,20,21] thermodynamic parameters were calculated, and adsorption was shown to be exothermic. Most of these studies, however, dealt with nonpolar adsorbates such as herbicides and pesticides, making it difficult to anticipate the effect of temperature in systems that contain polar molecules such as the benzene carboxylic acids.…”

The influence of temperature on the adsorption of mellitic acid onto goethite

“…Sorption into pores diminishes the efficacy of chemical extraction and reduces the bioavailability of such compounds [2,[5][6][7]. Studies of hydrophobic organic contaminants (HOCs) indicate that several physical and chemical mechanisms, including increased adsorption energy resulting from compound interaction within pores, may enhance HOC retention in mineral micropores with a porous adsorbents effectively remove organic compounds and heavy metals from contaminated waters [12][13][14][15][16][17][18][19]. Other evidence also supports the likelihood that mineral mesopores may enhance organic compound sorption processes.…”

Influence of mesoporosity on the sorption of 2,4-dichlorophenoxyacetic acid onto alumina and silica

“…The models of surface complex formation were successfully applied to describe the adsorption of metal ions, inorganic anions, and organic substances on the surface of oxide minerals [8][9][10].…”

Adsorption of Copper-Amino Acid Complexes on the Surface of Highly Dispersed Silica