Determination of sulfide by cathodic stripping voltammetry of silver sulfide films at a rotating silver disk electrode

Shimizu, Kunio; Osteryoung, R. A.

doi:10.1021/ac00227a006

Cited by 42 publications

(16 citation statements)

References 24 publications

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“…5c coincide with the experimental as well as the calculated potential shifts of Ref. 23. This proves that the sulfur layers remaining after the anodic stripping of cadmium or zinc behave like bulk sulfur.…”

Section: Resultssupporting

confidence: 88%

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CdS and ZnS Deposition on Ag(111) by Electrochemical Atomic Layer Epitaxy

Innocenti

Pezzatini

Forni

et al. 2001

J. Electrochem. Soc.

115

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We applied the electrochemical atomic layer epitaxy ͑ECALE͒ methodology to obtain deposits of CdS and ZnS on Ag͑111͒ by alternate underpotential deposition of the elements forming the compounds. The amounts of the elements deposited, determined by stripping coulometry, always yielded a stoichiometric 1:1 ratio. The deposits were formed using an automated electrochemical deposition system, described here, making use of a simple distribution valve.Recent work in our group is devoted to the growth of thin-film compound semiconductors on silver single crystals by electrochemical atomic layer epitaxy ͑ECALE͒. Stickney and co-workers developed this method to obtain structurally well-ordered II-VI and III-V compound semiconductors on gold at low cost. 1-3 The method is based on the alternate electrodeposition of atomic layers of the elements making up a compound, at underpotential. Underpotential deposition ͑UPD͒ is a surface-limited electrochemical phenomenon that results in the deposition of an atomic layer. A monolayer of the compound is obtained by alternating the UPD of the metallic element with the UPD of the nonmetallic element in a cycle. The ECALE cycle can be repeated as many times as necessary to obtain deposits of practical thickness, and the thickness of the deposit is determined by the number of cycles.The method requires the definition of precise experimental conditions, such as potentials, reactants, concentrations, supporting electrolytes, pH, deposition times, and the possible use of complexing agents. These conditions are strictly dependent on the compound one wants to form and on the substrate used. We found the conditions to grow practically all II-VI compound semiconductors and are now beginning to study the III-V compounds. The substrate that has been used up to now is Ag͑111͒, a single crystal to ensure the maximum probability for the epitaxial growth.In a previous paper we described the experimental conditions needed to obtain up to five sulfur layers and four cadmium layers of CdS. Sulfur layers were obtained by oxidative UPD from sulfide ion solutions, 4-6 whereas cadmium layers were obtained by reductive UPD from cadmium ion solutions. 7 Both precursors were dissolved in pyrophosphate plus sodium hydroxide of pH 12. The high pH was used to shift the hydrogen evolution toward very negative potentials in order to evidence the whole underpotential oxidation process of sulfide ions which takes place between Ϫ1.35 and Ϫ0.8 V/SCE. A strong complexing agent such as pyrophosphate was used to keep cadmium ions in solution at this high pH. This paper describes the growth of thicker deposits of CdS, up to 150 deposition cycles, obtained using an automated system. The deposit morphology was examined by scanning electron microscopy ͑SEM͒. This paper also describes conditions to form ZnS.The experimental conditions for CdS and ZnS growth on silver are different from those required on gold. 8-10 ExperimentalMerck analytical reagent-grade 3CdSO 4 •8H 2 O and Aldrich analytical reagent-grade Na 2 S were used ...

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Section: Resultssupporting

confidence: 88%

“…23. The cathodic stripping process of the sulfur deposited either on a stationary or on a rotating silver electrode was found not to be controlled by the diffusion of sulfide ions from the electrode surface but by other kinetics.…”

Section: Resultsmentioning

confidence: 86%

CdS and ZnS Deposition on Ag(111) by Electrochemical Atomic Layer Epitaxy

Innocenti

Pezzatini

Forni

et al. 2001

J. Electrochem. Soc.

115

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“…Another indication for the contemporary release of both cations is given by the successive cathodic stripping of S. In fact, once all of the metallic element has been stripped anodically, the remaining sulfur layers, except for the first, are reduced at more positive potentials than the first sulfur layer in contact with the silver substrate. The comparison with the cathodic stripping voltammetry of silver sulfide films described in [24] proves that the sulfur layers remaining after the anodic stripping of the cations behave like bulk sulfur. If part of the cations was not re-dissolved, or one of the two corresponding binary compounds still remained on the electrode, then the cathodic stripping curves should be shifted towards more negative potentials in a way symmetrical to the positive shift observed for the stripping curves of the cations.…”

Section: Systematic Investigation Of the Ternary Sulfide Obtained Witmentioning

confidence: 72%

Ternary cadmium and zinc sulfides and selenides: electrodeposition by ECALE and electrochemical characterization

Loglio

Innocenti

Pezzatini

et al. 2004

Journal of Electroanalytical Chemistry

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“…1.1.3.9) is extremely interesting because many of its substrates are of analytical import. These include galactose, lactose, glycerin, dihydroxyacetone, and glyceraldehyde (1 7, 18). We have previously demonstrated how galactose oxidase can be reversibly turned on and off by oxidizing and reducing it, respectively, using a thin-layer electrochemical cell and a mediator titrant (19).…”

Section: Resultsmentioning

confidence: 99%

Interactions of methylated adenine derivatives with the mercury electrode

Paleček¹,

Osteryoung²,

Osteryoung³

1982

Anal. Chem.

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Adenine and its methylated derlvatlves, 1-methyl-6-aminopurine, 3-methyl-6-amlni~purlne, Nmethyl-6-aminopurlne, and N,Ndlmethyl-6-aminopurine, were studied In alkallne solution by DC, normal pulse, and dlfferential pulse polarography and by cycllc voltammetry and cathodlc stripping voltammetry at hanging mercury drop electrodes. All save N,N-dimethyl-6-amlnopurlne gave polarographic currents and cathodic strlpplng peaks due to the formation of slightly soluble compounds with mercury. It was concluded that the 6-amino group of adenlne is the mercury bindlng slte In these cases. Cathodic strlpplng behavior suggests that l-methyl-6-amlnopurlne, 3-methyl-6-amlnopurlne, and N-methyl-6-amlnopurlne can be determined by cathodic strlpplng voltammetry, and that detection llmlts for N-metlhyl-6-amlnopurlne are comparable to those for adenlne (lo-' M).

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Determination of sulfide by cathodic stripping voltammetry of silver sulfide films at a rotating silver disk electrode

Cited by 42 publications

References 24 publications

CdS and ZnS Deposition on Ag(111) by Electrochemical Atomic Layer Epitaxy

CdS and ZnS Deposition on Ag(111) by Electrochemical Atomic Layer Epitaxy

Ternary cadmium and zinc sulfides and selenides: electrodeposition by ECALE and electrochemical characterization

Interactions of methylated adenine derivatives with the mercury electrode

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