Received: July 19, 2007

In Final Form: November 19, 2007

Abstract:

The influence of halide ions on the stability of gold nanoparticles nominally protected by a monolayer of dimethylaminopyridine (DMAP) or its conjugate acid (DMAPH⁺) is reported. The addition of NaF or NaCl to aqueous suspensions of DMAP(H⁺)-Au nanoparticles does not lead to flocculation or aggregation at high pH. In more acidic solutions, the presence of chloride ions causes the particles to aggregate whereas NaF has no effect. We have shown that this aggregation is not due to simple electrostatic screening but rather from the competitive adsorption between chloride and DMAP(H⁺) on the surface of the gold nanoparticles. Chronocoulometry on polycrystalline gold electrodes has been used to quantitatively describe the pH dependent competitive adsorption. At high pH, chloride ions are unable to displace DMAP from the gold surface, while at low pH the gold surface is covered by very high chloride coverages, and nearly no DMAP (or its conjugate acid DMAPH⁺) is found at the Gibbs interface. Only at intermediate pH (ca. 7.5), do the inorganic and organic species coexist on the gold surface. At pH 7.5, and for an equimolar mixture of chloride ions and DMAPH⁺, we have shown that each chloride ion displaces roughly one molecule and that this replacement is increasingly favorable as the surface charge of the metal becomes increasingly positive. We have also used zeta potential measurements to determine the electrical state of DMAP(H⁺)-Au nanoparticles. Our results indicate that stable DMAP(H⁺)-Au nanoparticles are characterized by a positive surface charge on the metal core even though the adsorbed monolayer is uncharged.

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