Electrochemical measurements, atomic force microscopy, and scanning tunneling microscopy have been
combined to present the first direct images of the potential-controlled phase transition between the
hemimicellar and condensed states of a dodecyl sulfate (SDS) film at the Au(111) electrode surface. The
adsorbed SDS forms stripe-shaped hemimicellar aggregates at small or moderate charge densities at the
electrode. High-resolution STM images of these aggregates revealed that adsorbed SDS molecules are
ordered and form a long-range two-dimensional lattice. A unit cell of this lattice consists of two vectors
that are 4.4 and 0.5 nm long and are oriented at an angle of 70°. We propose that each unit cell contains
two flat-laying SDS molecules stretched out along the longer axis of the cell with the hydrocarbon tails
directed toward the interior of the cell. The remaining SDS molecules in the hemimicelle assume a tilted
orientation. This long-range structure is stabilized by the interactions of sulfate groups belonging to the
adjacent cells. The sulfate groups of the flat-laying SDS molecules are arranged into a characteristic (√3
× √7) structure in which the sulfate groups along the √7 direction are bridged by hydrogen-bonded water
molecules. When the positive charge on the metal either becomes equal to or exceeds the charge of adsorbed
surfactant, the surface aggregates melt to form a condensed film. The transition between the hemimicellar
and condensed states of the film is reversible. The hemimicellar aggregates may be re-formed by decreasing
the charge density at the electrode surface. The charging and discharging of the gold electrode can be easily
controlled by a proper variation of the electrode potential.
A mixed bilayer of cholesterol and dimyristoylphosphatidylcholine has been formed on a gold-coated block of quartz by fusion of small unilamellar vesicles. The formation of this bilayer lipid membrane on a conductive surface allowed us to study the influence of the support's surface charge on the structure and hydration of the bilayer lipid membrane. We have employed electrochemical measurements and the specular reflection of neutrons to measure the thickness and water content in the bilayer lipid membrane as a function of the charge on the support's surface. When the surface charge density is close to zero, the lipid vesicles fuse directly on the surface to form a bilayer with a small number of defects and hence small water content. When the support's surface is negatively charged the film swells and incorporates water. When the charge density is more negative than -8 micro C cm(-2), the bilayer starts to detach from the metal surface. However, it remains in a close proximity to the metal electrode, being suspended on a thin cushion of the electrolyte. The field-driven transformations of the bilayer lead to significant changes in the film thicknesses. At charge densities more negative than -20 micro C cm(-2), the bilayer is approximately 37 A thick and this number is comparable to the thickness determined for hydrated multilayers of dimyristoylphosphatidylcholine from x-ray diffraction experiments. The thickness of the bilayer decreases at smaller charge densities to become equal to approximately 26 A at zero charge. This result indicates that the tilt of the acyl chains with respect to the bilayer normal changes from approximately 35 degrees to 59 degrees by moving from high negative charges (and potentials) to zero charge on the metal.
Chronocoulometry and the thermodynamic analysis of charge density data were employed to describe the energetics of sodium dodecyl sulfate (SDS) adsorption at the Au(111) electrode surface. Thermodynamic data such as the Gibbs excess, Gibbs energy of adsorption, and the film pressure of adsorbed SDS were determined for a broad range of electrode potentials, charge densities, and bulk SDS concentrations. The present results, combined with our previous scanning probe microscopy (SPM) studies, show that adsorption of SDS at the Au( 111) electrode surface has a two-state character. At small or moderate absolute charge densities, the adsorbed SDS molecules aggregate into hemicylindrical stripelike micelles. This state is well-ordered. The unit cell of its two-dimensional lattice consists of two vectors that are 44 and 5.0 Å long and are oriented at an angle of 70°. The Gibbs excess data indicate that five SDS molecules are accommodated into the unit cell. At large positive charge densities, the hemimicellar aggregates melt to form a condensed film. The surface concentration of SDS doubles upon transition from the hemimicellar to the condensed state. We have performed neutron reflectivity experiments to determine the thickness of the hemimicellar and condensed films. The neutron reflectivity data indicate that the thickness of the condensed film is equal to 20.5 Å and is only 30% larger than the thickness of the hemimicellar state. The electrochemical and neutron reflectivity data indicate that the properties of the condensed state are best explained by a model of an interdigitated film in which half of the sulfate groups are turned toward the metal and half toward the solution.
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