Underpotential deposition of copper on electrochemically treated polycrystalline Au surfaces

Cyclic voltammetric responses of electrochemically treated polycrystalline gold surfaces have been examined using Cu-UPD probe reactions (UPD-underpotential deposition). The treatment procedure used appears to induce preferential crystal orientation of the Au surface with a very small roughness factor and affords a simple method to obtain well-defined surfaces for electrochemical studies.     

Monolayer deposition of silver and copper onto platinum electrodes at non-equilibrium conditions

Ag and Cu were deposited in submonolayer amounts onto Pt electrodes at constant cathodic potentials within the hydrogen adsorption region. Rectangular pulses of Cu²⁺ or Ag⁺ fluxes to the Pt surface were generated by a Cu or Ag generator electrode using the twin electrode thin-layer technique. The analysis of the response currents of the Pt electrode yields in formation about the metal deposition process at non-equilibrium conditions. Cu and Ag were found to deposit directly as monolayers and not at random. The displacement of adsorbed hydrogen was measured as a function of the quantity of metal deposited.     

Underpotential deposition studies of copper on glassy carbon

Studies on the deposition and dissolution of copper from 0·5 M sulphuric acid solutions onto glassy carbon (GC) using potential sweep techniques indicated that an additional peak occurs at higher positive potentials than the bulk stripping peak. This peak is identified as due to the stripping of underpotential deposited (UPD) copper. Results of investigations on the effect of sweep rate, deposition potential and time of deposition on the peak characteristics of UPD and bulk deposited copper are also reported.     

Underpotential deposition of Cu on partially oxidized Rh electrodes

The underpotential deposition (UPD) of copper on partially oxidized rhodium electrodes was studied in acid medium using potentiodynamic techniques. The process was analyzed as a function of the potential and time of deposition. The potentiodynamic I-E patterns for the oxidative dissolution of Cu provide evidence for the existence of a chemical reaction between Cu and oxygen existing on the electrode surface. Redistribution of the active sites is also possible when appreciable quantities of oxidized species are simultaneously reduced by the UPD process. The partially oxidized rhodium electrodes were prepared by cyclic voltammetry and anodic polarization. The later method provided the most oxidized surfaces, but, even in this case, the degree of oxygen surface coverage was lower than that corresponding to a monolayer. Received: 11 July 1997 / Accepted: 10 February 1998     

Underpotential deposition and anodic stripping voltammetry at mesoporous microelectrodes

Using the technique of liquid crystal templating a series of high surface area mesoporous platinum microelectrodes was fabricated. The underpotential deposition of metal ions at such electrodes was found to be similar to that at conventional platinum electrodes. The phenomena of underpotential deposition, in combination with the intrinsic properties of mesoporous microelectrodes (i.e. a high surface area and efficient mass transport) was exploited for the purpose of anodic stripping voltammetry. In particular the underpotential deposition of Ag(+), Pb(2+) and Cu(2+) ions was investigated and it was found that mesoporous microelectrodes were able to quantify the concentration of ions in solution down to the ppb range. The overall behaviour of the mesoporous electrodes was found to be superior to that of conventional microelectrodes and the effects of interference by surfactants were minimal.     

Investigation of ruthenium deposition onto a platinized platinum electrode in sulfuric acid media

Ruthenium deposition onto platinized Pt electrode in 0.5 M H₂SO₄ solution is investigated. The I–V profiles of the Pt electrode covered with Ru depend on the potential of Ru deposition. This phenomenon is explained by the increasing degree of oxidation of the Ru layers deposited at higher potentials. Oxidation of Ru deposited at low potentials begins with comparatively slow processes. A mechanism for Ru deposition via ionization of hydrogen adsorbed on platinized Pt electrode is proposed.     

Underpotential deposition of copper on electrodes modified with colloidal gold

This communication is concerned with the electrochemical addressability of gold colloidal particles deposited on a conducting substrate. Cyclic voltammetry of electrodes modified with gold colloid layers indicates that an underpotential deposition of copper onto the gold surface takes place. Analysis of the charge associated with the underpotential deposition permits the electroactive gold area to be calculated. The total gold area may be determined from transmission electron microscopy (TEM) images. Comparison of the geometric and electroactive areas obtained indicates that electrochemically all the gold particles are addressable and the entire colloid surface is accessible.     

Rhenium deposition onto platinum surface by reduction of perrhenic acid with methanol in hydrochloric acid media

It has been demonstrated that rhenium deposition onto Pt surface in hydrochloric acid media can also be carried out by reduction of perrhenic acid with methanol. Above 0.5 M Cl⁻ ion concentration, however, it is practical to combine the use of methanol with hydrogen.     

Peculiarities of copper underpotential deposition and nucleation on polycrystalline platinum in the presence of acetonitrile: Rotating ring-disk electrode

The initial stages of copper electrocrystallization on polycrystalline platinum in 0.5 M H₂SO₄ + 10 mM CuSO₄ + 0–200 mM acetonitrile (AcN) solutions are studied by the methods of cyclic voltammetry and potentiostatic current transients on a ring-disk electrode. Adsorbed AcN molecules accelerate both the underpotential deposition and the bulk deposition of copper due to the local electrostatic effects on the charged interface. With the increase in the additive concentration in solution, the contribution of the production of copper ions Cu⁺ is observed to increase due to the formation of Cu(AcN) _x ⁺ comlexes, particularly, for [AcN] ≥ 4 mM when the concentrations of acetonitrile and copper sulfate become comparable. In the presence of AcN, as well as in the copper sulfate supporting electrolyte, the adatomic layer is formed via the mechanism of the two-dimensional growth of Cu(1 × 1) phase islets.     

Sorption of nickel and cobalt ions onto cobalt and nickel ferrites

The corrosion of the metal parts in the primary circuit of pressurized water reactors leads to the release of colloidal particles (NiFe(2)O(4), CoFe(2)O(4), NiO, Ni...) and ionic species (Co, Ni, Cr...). Particles can interact with ionic species in the primary medium, contributing to their transport and to their deposition onto surfaces outside the neutron flux generating radioactive contamination. Sorption and zetametry experiments at 25 °C were performed on the Ni(2+)/CoFe(2)O(4) and Co(2+)/NiFe(2)O(4) systems in order to determine the behaviour of corrosion products in the fluid of the primary circuit. Sorption appears as surface complexation starting from pH 6 and is followed by precipitation of hydroxide above pH 7.5. Complexation and solubility constants were obtained from the modelling of sorption curves. The two oxide systems present a very similar sorption behaviour, but some differences, due to their different isoelectric points, could be observed on zetametric measurements.     

Electrochemical reduction of mesoxalic acid on polycrystalline platinum surfaces

The electrochemical reduction of mesoxalic acid on polycristalline platinum surfaces has been studied in acid medium. The reaction proceeds through the interaction with adsorbed hydrogen atoms. Malonic acid is proposed as final reaction product.

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Elektrochemische Reduktion von Mesoxalsäure auf polykristallinen Platinoberflächen

Zusammenfassung Die elektrochemische Reduktion von Mesoxalsäure auf polykristallinen Platinoberflächen wurde in saurem Medium untersucht. Die Reaktion verläuft über die Wechselwirkung mit adsorbierten Wasserstoffatomen, wobei als Endprodukt Malonsäure entsteht.

     

Cobalt electrodeposition onto polycrystalline gold from ammoniacal solutions

In the present work, the cobalt electrodeposition onto polycrystalline gold electrodes from aqueous solutions containing 0.01M CoSO₄ + 1 M (NH₄)₂SO₄ at pH=7 was analyzed. Linear voltammetry results suggested a change in the kinetic of the cobalt electrodeposition. In all cases, the nucleation rate (A), the number of active nucleation sites (N ₀) and the saturation number of nuclei (N _s ) values were potential dependent. The calculated Gibbs free energy (ΔG) for this system was 1.88×10^?20 J nuclei^?1 and the transfer coefficient for the Hydrogen Electroreduction Reaction (HER) was 0.47.      

Crystal-face-selective adsorption of Au nanoparticles onto polycrystalline diamond surfaces

Crystal-face-selective adsorption of Au nanoparticles (AuNPs) was achieved on polycrystalline boron-doped diamond (BDD) surface via the self-assembly method combined with a UV/ozone treatment. To the best of our knowledge, this is the first report of crystal-face-selective adsorption on an inorganic solid surface. Hydrogen-plasma-treated BDD samples and those followed by UV/ozone treatment for 2 min or longer showed almost no adsorption of AuNP after immersion in the AuNP solution prepared by the citrate reduction method. However, the samples treated by UV/ozone for 10 s showed AuNP adsorption on their (111) facets selectively after the immersion. Moreover, the sample treated with UV/ozone for 40-60 s showed AuNP adsorption on the whole surface. These results indicate that the AuNP adsorption behavior can be controlled by UV/ozone treatment time. This phenomenon was highly reproducible and was applied to a two-step adsorption method, where AuNPs from different batches were adsorbed on the (111) and (100) surface in this order. Our findings may be of great value for the fabrication of advanced nanoparticle-based functional materials via bottom-up approaches with simple macroscale procedures.     

Underpotential deposition and involved alloy formation of cadmium on silver particles modified HOPG substrates

Cadmium underpotential deposition (UPD) on Ag particles modified highly ordered pyrolytic graphite (HOPG) surfaces, and the involved alloy formation were studied by conventional electrochemical techniques. Voltammetric results indicated that the Cd UPD followed an adsorption behavior different from that observed for massive Ag electrodes and Ag particles supported on vitreous carbon. Nanometer-sized bimetallic Cd–Ag particles were characterized by ex situ atomic force microscopy (AFM). Initially, AFM images show Ag deposits of similar size distributed preferably on HOPG step edges. No remarkable morphological changes are observed on the surface after the subsequent Cd deposition, suggesting that the Cd particles are deposited selectively over the Ag crystals. From the analysis of desorption spectra, employing different polarization times, and density functional theory (DFT) calculations, the formation of a Cd–Ag surface alloy could be inferred.     

Lateral modification and organization of mixed adlattices on polycrystalline platinum electrodes

Linear scan voltammetry of carbon monoxide on platinum was conducted with the electrode surface modified by coadsorbed organic and inorganic compounds (surface lateral modifiers). The current-potential peak of carbon monoxide electrooxidation moved in the positive direction in all cases studied. Two mechanistic components are proposed to account for our observation. The structural effects are related to the nucleation-growth mechanism of the oxidation which assigns the reaction zone to the perimeter of the growing islands of a surface oxidant. Electrooxidation of an ideally uniform and coherent CO adlattice should be unaffected by a modifier present outside of such islands. On the contrary, many small islands of CO, diluted by the two dimensional network of the surface modifiers, create a favorable situation for the lateral modification. The modifier's induced transitions between small and large islands are reflected in the shift of the CO oxidation peak potential.The second component relates to the redistribution of the modifier's electronic charge between the surface and the chemisorbed CO. A part of the charge is localized on the 5σ(CO)-5d(Pt) bond and increases the stability of surface attached CO. The electronic charge shifted towards the metal, can also screen the reacting CO/H₂O system against the growing electric field during the potential scan. Both effects are interpreted to increase the overpotential of the electrooxidation of CO and contribute to the gross effect observed experimentally.     

The surface characteristics of polycrystalline cobalt electrooxidised in sulfuric acid solutions

The oxidation of cobalt electrodes has been carried out by means of cyclic voltammetry and coulometry under controlled potential in sulfuric acid solutions of different concentrations. The electrochemical scanning tunneling microscope/scanning tunneling microscope (ECSTM/STM) systems constructed by the authors and scanning electron microscopy (SEM) with the SEM-EDX system of surface analysis of the elements have been used. The procedure applied in this work made it possible to observe the fragments of the same surface by means of SEM and ECSTM/STM. The most typical images for a polycrystalline Co electrode with a ±10% accuracy at the scales of 4800 nm × 4800 nm and 100 nm × 100 nm are presented and the results are discussed. In a diluted electrolyte (0.1 M), irregular forms of a stable cobalt oxide with Co:O ratio ∼1:1 appear. Unreproducible results have been obtained in a 1.0 M H₂SO₄ solution. Compact and relatively regular layers of cobalt oxide of the same ratio have been obtained in 0.1 M H₂SO₄, as well as in 10.0 M sulfuric acid solution, under controlled oxidation potential at the passivation range. Received: 6 January 1999 / Accepted: 5 May 1999     

Underpotential deposition of hydrogen on benzene-modified Pt(111) in aqueous H2SO4

The Pt(111) electrode is modified by an overlayer of C6H6 (ads) upon its cycling in the 0.05-0.80 V range in aq H2SO4 + 1 mM C6H6. The C6H6 (ads) overlayer significantly changes the underpotential-deposited H (H(UPD)) and anion adsorption, and cyclic-voltammetry (CV) profiles show a sharp cathodic peak and an asymmetric anodic one in the 0.05-0.80 V potential range. The C6H6 (ads) layer blocks the (bi)sulfate adsorption but facilitates the adsorption of one monolayer of H(UPD). Cycling of the benzene-modified Pt(111) in benzene-free aq 0.05 H2SO4 from 0.05 to 0.80 V results in a partial desorption of C6H6 (ads) and in a partial recovery of the CV profile characteristic of an unmodified Pt(111). The peak potential of the cathodic and anodic feature is independent of the scan rate, s (10 < or = s < or = 100 mV s(-1)), and the peak current density increases linearly with an increase of the scan rate. Temperature variation modifies the peak potential and current density but does not affect the charge density of the cathodic or anodic feature. Temperature-dependent studies allow us to determine the thermodynamic state function for the H(UPD) adsorption and desorption. Delta G degrees(ads)(H(UPD))assumes values from -4 to -12 kJ mol(-1), while has values from 9 to 14 kJ mol(-1). The values of delta Delta G degrees (delta Delta G degrees = delat Delta G degrees(ads) + delta Delta D degrees(des)) decrease almost linearly from 6 kJ mol(-1) at theta(H(UPD) --> 0 to 0 kJ mol(-1) at theta(H(UPD) --> 1. The nonzero values of delta Delta G degrees testify that the adsorbing and desorbing H(UPD) adatoms interact with an energetically different substrate. The lateral interactions changed from repulsive (omega = 29 kJ mol(-1) at theta(H(UPD) --> 0) to attractive (omega = -28 kJ mol(-1) at theta(H(UPD) --> 1) as the H(UPD) coverage increases. The values of delta S degrees(ads)(H(UPD)) increase from 19 to 56 J K(-1) mol(-1), while those of delta S degrees(des)(H(UPD)) decrease from 45 to -30 J K(-1) mol(-1) with an increase of H(UPD) coverage. The values of delta H degrees(des)(H(UPD)) and delta H degrees(des)(H(UPD)) vary from 0 to 27 kJ mol(-1). The Pt(111)-H(UPD) surface bond energy at the benzene-modified Pt(111) electrode falls in the 191-218 kJ mol(-1) range and is weaker than in the case of the unmodified Pt(111) electrode in the same electrolyte.