Water Absorbency by Wool Fibers:  Hofmeister Effect

Abstract: Wool is a complex material, composed of cuticle and epicuticle cells, surrounded by a cell membrane complex. Wool fibers absorb moisture from air, and, once immersed in water, they take up considerable amounts of liquid. The water absorbency parameter can be determined from weight gain, according to a standard method, and used to quantify this phenomenon. In this paper we report a study on the water absorbency (or retention) of untreated wool fibers in the presence of aqueous 1 M salt solutions at 29 degrees C… Show more

“…Furthermore, azide-anions posses similar free energy of hydration values [− G hydr ] and water absorbance properties [A W ] [58] as observed for SCN. Also an investigation on the electron-transfer properties of nucleophilic anions to 1-pyrenesulfonic acid radical cation (Py + SA¯) in Nafion membranes provide similar attenuation factors [AF] for both, SCN and N3 for the difference in quenching within the membranes and in bulk solution [57].…”

Optimization of a ligand immobilization and azide group endcapping concept via “Click-Chemistry” for the preparation of adsorbents for antibody purification

“…Furthermore, azide-anions posses similar free energy of hydration values [− G hydr ] and water absorbance properties [A W ] [58] as observed for SCN. Also an investigation on the electron-transfer properties of nucleophilic anions to 1-pyrenesulfonic acid radical cation (Py + SA¯) in Nafion membranes provide similar attenuation factors [AF] for both, SCN and N3 for the difference in quenching within the membranes and in bulk solution [57].…”

Optimization of a ligand immobilization and azide group endcapping concept via “Click-Chemistry” for the preparation of adsorbents for antibody purification

“…8b. Instead of using the inverse surface excess of water values of the alkali halides to characterise their impact, the anionic polarizabilities [46,74], α Y , could be used (in Å 3 ): α F − = 0.9, α Cl − = 3.4, α Br − = 4.84 and α I − = 7.4 [75]. The following correlation is found: Γ −1 w (NaY; mol −1 m 2 ) = 9521α Y + 20272 (R 2 = 1).…”

“…[36][37][38], it is important to consider the behaviour of electrolytes (e.g., depletion/accumulation) at macroscopic interfaces, in particular at the air/water (a/w) interface [39][40][41][42][43]. Recently, dispersion forces have been allocated an important role in controlling the distribution of ions at the a/w interface, as well as at the interface between the solute and the surrounding aqueous solution [44][45][46]. Surface concepts have been applied in various ways to understand salting-out/-in effects [47][48][49][50][51][52].…”

Lower consolute boundaries of the nonionic surfactant C8E5 in aqueous alkali halide solutions: An approach to reproduce the effects of alkali halides on the cloud-point temperature

“…Accordingly, small ions of high charge density bind water tightly, whereas large monovalent ions of low charge density bind water weakly, relative to water-water interaction strength: this is expressed by the Jones-Dole viscosity B coefficients (19). However, the relative position in the series should be considered as indicative only because there will be considerable variation depending on type of protein, pH, temperature, and ion pair effects (22).…”

Role of Chloride Ions in Modulation of the Interaction between von Willebrand Factor and ADAMTS-13