Wetting Phenomena at the Free Surface of the Isotropic Phase of a Smectic Liquid Crystal

Lucht, Robert P.; Bahr, Christian

doi:10.1103/physrevlett.78.3487

Cited by 39 publications

(27 citation statements)

References 24 publications

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“…52 The influence of packing on the surface orientation of uncharged pyridinium rings was also recently hypothesized on the basis of observed steplike changes of the adsorption isotherm. 53 For this uncharged molecule, a possible origin in terms of attractions between the aromatic rings was suggested.…”

Section: Resultsmentioning

confidence: 99%

Orientation and Order of Aqueous Organic Ions Adsorbed to a Solid Surface

Sukhishvili

Granick

1999

J. Phys. Chem. B

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The adsorption and orientation of an aqueous organic ion with anisotropic shape (1,4-dimethylpyridinium, P + ) at the surface of oxidized silicon carrying opposite charge (produced by conditions of high pH) were studied using polarized infrared spectroscopy in attenuated total reflection (FTIR-ATR). Orientation relative to the surface was quantified from the dichroic ratio of in-plane skeletal vibrations of the pyridinium ring (1643 and 1523 cm -1 ), and the adsorbed amount was inferred from the intensity of these bands. The sticking energy of the organic ion was slightly larger than that of small inorganic ions of the same charge (Li + , Na + , Cs + ). From relative quantities adsorbed in competitive adsorption, the relative sticking energy was quantified (∼7k B T relative to Na + at pH ) 9.2 and varying in the order Cs + > Na + > Li + by the total amount of 0.6k B T). At low ionic strength (no inorganic ions present except those in the buffer solution), P + stood preferably parallel to the surface when the surface coverage was low but more nearly upright both as its surface coverage increased and as the concentration of coadsorbed small ions increased. This shows the influence of steric packing on the orientation of this ion of asymmetric shape. The larger the hydrated diameter of the coadsorbed ion, the more the P + ion tilted away from the surface (H + < Li + , Na + , Cs + < Mg 2+ ). Furthermore, if the mass adsorbed exceeded a critical level, both the tilt and the amount adsorbed jumped in response to increasing P + concentration in bulk solution, with hysteresis upon dilution. This jump, together with the measured ellipsometric thickness and contact angle, suggests that the discontinuity involved structural change within a single monolayer. The organic ion thus behaved at the surface as an embryonic amphiphile, although in the bulk, micelle formation has not been reported.

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Section: Resultsmentioning

confidence: 99%

Orientation and Order of Aqueous Organic Ions Adsorbed to a Solid Surface

Sukhishvili

Granick

1999

J. Phys. Chem. B

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“…While a continuous transition has only been observed for the case of pentane on water, 3 first-order transitions have been reported for a variety of systems: complex organic liquids, 4 near-critical liquid mercury 5 and binary liquid crystal mixtures. 6 A signature of the first-order nature of the transition in these systems is the characteristic jumps in the coverage ͑''prewetting'' transitions͒ which extend away from the vapor-fluid coexistence curve. 7 Although wetting transitions are ubiquitous in nature whenever one has control over the surface-field strength ͑this may be achieved, for example, by preplating the substrate with a monolayer of a foreign species͒, in the case of one component films physisorbed on solid surfaces, genuine wetting transitions in the liquid phase have been experimentally observed only for quantum fluids on heavy alkali metals 8,9 and for Ne on Rb.…”

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confidence: 99%

First-order wetting transitions of neon on solid CO2 from density functional calculations

Ancilotto

Toigo

2000

The Journal of Chemical Physics

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“…First-order wetting transitions have been found in binary liquid mixtures, 6 in near-critical liquid and vapor mercury, 7 in binary liquid crystals mixtures, 8 and in metallic salt melts. First-order wetting transitions have been found in binary liquid mixtures, 6 in near-critical liquid and vapor mercury, 7 in binary liquid crystals mixtures, 8 and in metallic salt melts.…”

Section: Introductionmentioning

confidence: 99%