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Electrocatalytic Sensing of Carbon Dioxide, Oxygen and Inert Inorganic Analytes at Network Films of Transition Metal Complexes

Kulesza, Pawel J ; Wadas, Anna ; Ozimek, Weronika ; [et al.]

The Electrochemical Society ; 2016

In: ECS Meeting Abstracts Vol. MA2016-02, No. 51 ( 2016-09-01), p. 3864-3864

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2016-02, No. 51 ( 2016-09-01), p. 3864-3864

Abstract: There has been growing interest in electrocatalytic sensing of inert reactants that exhibit totally irreversible behavior at common electrode substrates. For example, catalytic reductive transformations of carbon dioxide (CO 2 ) to fuels and to commodity chemicals are important contemporary energy and environmental challenges. Because CO 2 is very stable, the direct electroreduction of CO 2 to CO requires large over-potentials. On analytical grounds, there is a need to develop new methods for the determination of arsenic (electrochemically very inert basically at all oxidation states) due to its high toxicity and increasing population in the environment. At present chromatographic and spectroscopic approaches are the most common. Electrochemical methods for determination of arsenic are often considered as complimentary ones because they are fairly simple and they do not required generation of toxic AsH 3 . Our interests also concern electrochemical performance and electroanalysis of bromate (slow complex reduction) as well as electroreduction and sensing of oxygen. In the process of developing of new micro- and nanostructured electrocatalytic systems, we have concentrated on the network films yielding nanostructured metallic palladium via reduction of the complex of palladium(II), [Pd(C 14 H 12 N 2 O 3 )Cl 2 ] 2 ∙MeOH. The catalytic activity of CO 2 reduction was estimated from the oxidation charge of the adsorbed products. The adsorbed products obviously interfere with the formation of the oxide film on the Pd surface. The concept of generation and utilization of metallic (Pt, Ru, Au, Pd) nanostructures within the supramolecular organic networks will also be extended to the formation of electrocatalytic interfaces of importance to probing the redox behavior of arsenic(III), arsenic(V), bromate(V) and dioxygen. The rotating ring (platinum)-disk (glassy carbon) electrode methodology is employed for the characterization of different catalysts during the electrode processes mentioned above. For example, with respect to oxygen reduction, the rotating ring disk electrode has been employed for the studies in 0.1 M KHCO 3 and 0.1 mol dm -3 KH 2 PO 4 /K 2 HPO 4 (pH = 6.8) solutions. The results revealed that the specific activity of palladium nanocenters generated within the coordination architecture of tridentate Schiff-base-ligands by electrodeposition from the supramolecular complex of palladium(II), [Pd(C 14 H 12 N 2 O 3 )Cl 2 ] 2 ∙MeOH is higher than that of commercial Pd particles. Having in mind systems resulting in the enhancement of the electrooxidation of arsenic (III), we will consider various noble metals nanoparticles for example Pt, PtRu, Rh, Au, Pd that are capable of inducing the arsenic (III) oxidation in acidic medium. The recorded currents will be compared to those observed previously at the electrodes modified with a thin film of oxocyanorutheneate that is probably the most potent system so far for the electrocatalytic oxidation of As(OH) 3 . Reduction of arsenic (V) is even more inert but we have observed promising results in acidic medium at platinum and platinum-ruthenium nanoparticles. In other words, both processes, oxidation and reduction of arsenic species, can be successfully investigated at bare or modified (e.g. polyoxometallate functionalized) platinum nanoparticles. Network films of metal nanoparticles also permit preconcentration of arsenic species on their surfaces. The stripping steps would allow determination of low concentrations of arsenic (10 -6 mol/dm -3 or lower). All effects are particularly evident from the increases of currents with increases of concentration of arsenic species in the solution.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2016-02/51/3864

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

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Application of Coordinatively Supported and Activated Metal Nanocenters As Electrocatalytic Systems for Reduction of Carbon Dioxide

Wadas, Anna ; Rutkowska, Iwona Agnieszka ; Kulesza, Pawel J

The Electrochemical Society ; 2015

In: ECS Meeting Abstracts Vol. MA2015-01, No. 25 ( 2015-04-29), p. 1538-1538

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2015-01, No. 25 ( 2015-04-29), p. 1538-1538

Abstract: There has been growing interest in the electrochemical reduction of carbon dioxide (CO 2 ), a potent greenhouse gas and a contributor to global climate change, and its conversion into useful carbon-based fuels or chemicals. Numerous homogeneous and heterogeneous catalytic systems have been proposed to induce the CO 2 reduction and, depending on the reaction conditions (applied potential, choice of buffer, its strength and pH, local CO 2 concentration or the catalyst used), various products that include carbon monoxide, oxalate, formate, carboxylic acids, formaldehyde, acetone or methanol, as well as such hydrocarbons as methane, ethane, and ethylene, are typically observed at different ratios. These reaction products are of potential importance to energy technology, food research, medical applications and fabrication of plastic materials. Given the fact that the CO 2 molecule is very stable, its electroreduction processes are characterized by large overpotentials, and they are not energy efficient. To produce highly efficient and selective electrocatalysts, the transition-metal-based molecular materials are often considered. Because reduction of CO 2 can effectively occur by hydrogenation, in the present work, we concentrate first on such a model catalytic system as nanostructured metallic palladium capable of absorbing reactive hydrogen in addition to the ability to adsorb monoatomic hydrogen at the interface. We are going to demonstrate that palladium nanocenters can be generated within the coordination architecture of tridentate Schiff-base-ligands by electrodeposition from the supramolecular complex of palladium(II), [Pd(C 14 H 12 N 2 O 3 )Cl 2 ] 2 ∙MeOH. The resulting Pd nanoparticles (diameters, 5-10 nm) are stabilized and activated by nitrogen coordination sites, and the electrocatalytic system exhibits appreciable activity toward reduction carbon oxide (IV) in 0.1 mol dm -3 KHCO 3 . The respective voltammetric peak currents are ca. three times larger than those observed at conventional palladium nanoparticles (diameter, ca. 10-20 nm) under analogous experimental conditions and at the same loading of palladium (100 μg cm -2 ). Despite that fact that the degree of agglomeration of nanostructured palladium is much lower when it has been generated within the macromolecular network, it is reasonable to expect that some specific interactions between nitrogen coordination centers and metallic Pd exist. The process of electrosorption of hydrogen at the Schiff-base-ligand supported palladium nanostructures seems to be more reversible (when investigated in KHCO 3 ) and dominated by the hydrogen absorption rather than the surface adsorption phenomena (characteristic of conventional Pd nanoparticles). We are also going to address the possibility of utilization of the tridentate Schiff-base-ligand coordination architectures as matrices for cobalt and cooper catalytic sites during electrooxidation of carbon dioxide. We acknowledge collaboration with Adam Gorczynski, Maciej Kubicki, and Violetta Patroniak from Faculty of Chemistry, Adam Mickiewicz University, Poznan, Poland that has led to fabrication of supramolecular coordination compounds.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2015-01/25/1538

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2015

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Conducting-Polymer-Supported Bacterial Biofilms As Active Matrices for Noble Metal and Molecular Catalytic Centers: Enhancement of Electroreduction of Oxygen and Carbon Dioxide

Kulesza, Pawel J ; Seta, Ewelina ; Lotowska, Weronika ; [et al.]

The Electrochemical Society ; 2016

In: ECS Meeting Abstracts Vol. MA2016-01, No. 34 ( 2016-04-01), p. 1666-1666

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2016-01, No. 34 ( 2016-04-01), p. 1666-1666

Abstract: Hybrid matrices composed of porous conducting polymer - polyaniline (PANI) or poly(3,4- ethylenedioxythiophene) (PEDOT) - underlayer, robust bacterial biofilm and the multi-walled carbon nanotubes have been demonstarted to function as highly active supports for dispersed catalztic centers (both noble metal nanoparticles and molecular ligand complexes). We explore unique properties of biofilms, i.e. polymeric aggregates of microorganisms, in which cells adhere to each other on the electrode surfaces. Such systems are characterized by extracellular electron transfers involving c-type cytochromes (heme-containing proteins). Biofilms grown on inert carbon electrode substrates tend to exhibit electrocatalytic properties towards oxygen and hydrogen peroxide reductions in neutral media. The processes have been found to be further enhanced by introduction of multi-walled carbon nanotubes (MCNTs) that are modified with ultra-thin layers of organic (e.g. 4-(pyrrole-l-yl) benzoic acid. We expect here attractive electrostatic interactions between carboxyl-group containing anionic adsorbates and positively charged domains of the biofilm with c-type cytochrome enzymatic sites. Coexistence of the above components leads to synergistic effect that is evident from positive shift of the oxygen reduction voltammetric potentials and significant increase of voltammetric currents. Most likely, the reduction of oxygen has been initiated at the molecular (e.g. intentionally added cobalt porphyrin redox centers), whereas the undesirable hydrogen peroxide intermediate are further decomposed at the cytochrome sites. Among other important observations is the significant enhancement of activity of Pt nanoparticles toward electroreduction of carbon dioxide in the presence of such a robust bacterial biofilm as Y. enterocolitica. Although interactions between platinum and such a complex ecosystem as biofilm are difficult to describe precisely, it is reasonable to postulate some inhibition of the hydrogen evolution (competitive reaction) at platinum nanoparticles in presence of bacterial microcolonies in favor of enhancement of the CO 2 -reduction. It is also noteworthy that biofilms are highly hydrated, and existence of open water channels between the bacterial microcolonies facilitates flow of supporting electrolyte. Combination of the hydrophobic polymer (PANI) structures with hydrophilic bacterial aggregates seems to produce attractive hybrid supports for electrocatalysts operating in aqueous media. Based on numerous repetitive diagnostic experiments in both argon and carbon dioxide saturated electrolytes, it can be stated that, by growing and supporting the biofilm onto the PANI polymer underlayer, the overall stability of the biofilm-based system has been improved. Indeed, we have not effectively observed any degradation of the hybrid catalytic films (both in terms of electrocatalytic activity and physicochemical stability) during our prolonged diagnostic experiments. Because measurements have been performed in neutral (phosphate buffer at pH=6.1) rather than acid medium, the PANI films (regardless of the presence of some HSO 4 - anions) are not expected to be very well conducting. Consequently, we have also introduced MWCNTs to the electrocatalytic interface to facilitate charge distribution there.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2016-01/34/1666

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

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4

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Hierarchical and Selective Systems for Photoelectrochemical and Electrocatalytic Reduction of Carbon Dioxide

Kulesza, Pawel J ; Rutkowska, Iwona Agnieszka ; Solarska, Renata ; [et al.]

The Electrochemical Society ; 2017

In: ECS Meeting Abstracts Vol. MA2017-02, No. 45 ( 2017-09-01), p. 1968-1968

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2017-02, No. 45 ( 2017-09-01), p. 1968-1968

Abstract: There has been growing interest in the photoelectrochemical conversion of carbon dioxide (a potent greenhouse gas and a contributor to global climate change) to useful carbon-based fuels or chemicals. The reaction products are of potential importance to energy technology, food research, medical applications and fabrication of plastic materials. Given the fact that the CO 2 molecule is very stable, its electroreduction processes are characterized by large overpotentials. It is often postulated that, during electroreduction, the rate limiting step is the protonation of the adsorbed CO product to form the CHO adsorbate. In this respect, the proton availability and its mobility at the photo(electro)chemical interface has to be addressed. On the other hand, competition between such parallel processes as hydrogen evolution and carbon dioxide reduction has also to be considered. Recently, we have concentrated on the development of hybrid materials by utilizing combination of metal oxide semiconductors thus capable of effective photoelectrochemical reduction of carbon dioxide. For example, the combination of titanium (IV) oxide and copper (I) oxide has been considered before and after sunlight illumination. Application of the hybrid system composed of both above-mentioned oxides resulted in high current densities originating from photoelectrochemical reduction of carbon dioxide mostly to methanol (CH 3 OH) as demonstrated upon identification of final products. Among important issue is intentional stabilization, activation, and functionalization of the mixed-metal-oxide-based photoelectrochemcal interface toward better long-term performance and selectivity production of small organic molecules (C1-C4) and other chemicals. In this respect, ultra-thin films of conducting polymers (simple or polyoxometallate-derivatized) and supramolecular complexes (with nitrogen containing ligands and certain transition metal sites), sub-monolayers of metals (Cu, Au), networks of noble metal (Au, Ag) nanoparticles or layers of robust bacterial biofilms have been considered. The photo-biocathode with Cu-containing enzyme has induced the reduction of not only oxygen but carbon dioxide as well, under illuminations with photon energies higher than silicon band gap. In the presentation, special attention will be paid to mechanistic aspects of electroreduction of carbon dioxide, fabrication and characterization of highly selective and durable semiconductor photoelectrode materials and to importance of the reaction conditions.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2017-02/45/1968

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2017

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5

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(Invited) Modification of Electrocatalytic and Photoelectrochemical Interfaces Toward More Efficient Reduction of Carbon Dioxide

Kulesza, Pawel J ; Wadas, Anna ; Szaniawska, Ewelina ; [et al.]

The Electrochemical Society ; 2017

In: ECS Meeting Abstracts Vol. MA2017-01, No. 32 ( 2017-04-15), p. 1553-1553

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2017-01, No. 32 ( 2017-04-15), p. 1553-1553

Abstract: There has been growing interest in the photoelectrochemical conversion of carbon dioxide to useful carbon-based fuels or chemicals. Given the fact that the CO 2 molecule is very stable, its electroreduction processes are characterized by large overpotentials. It is often postulated that, during electroreduction, the rate limiting step is the protonation of the adsorbed CO product to form the CHO adsorbate. In this respect, the proton availability and its mobility at the photo(electro)chemical interface has to be addressed. On the other hand, competition between such parallel processes as hydrogen evolution and carbon dioxide reduction has also to be considered. Recently, we have concentrated on the development of hybrid materials by utilizing combination of metal oxide semiconductors thus capable of effective photoelectrochemical reduction of carbon dioxide. For example, the combination of titanium (IV) oxide and copper (I) oxide has been considered before and after sunlight illumination. Application of the hybrid system composed of both above-mentioned oxides resulted in high current densities originating from photoelectrochemical reduction of carbon dioxide mostly to methanol (CH 3 OH) as demonstrated upon identification of final products. Among important issue is intentional stabilization, activation, and functionalization of the mixed-metal-oxide-based photoelectrochemcal interface toward better long-term performance and selectivity production of small organic molecules (C1-C4) and other chemicals. In this respect, ultra-thin films of conducting polymers (simple or polyoxometallate-derivatized) and supramolecular complexes (with nitrogen containing ligands and certain transition metal sites), sub-monolayers of metals (Cu, Au), networks of noble metal (Au, Ag) nanoparticles or layers of robust bacterial biofilms have been considered. We are also going to demonstrate that the photoinduced electron from semiconductor conduction band is capable of activation of the active center of the metalo-enzyme molecule. Here the.nanostructured silicon material has been chosen as the substrate for the enzyme adsorption. In this case the p-type Si(111) was etched toward formation of the bunched steps on the surface. The photo-biocathode with Cu-containing enzyme has induced the reduction of not only oxygen but carbon dioxide as well, under illuminations with photon energies higher than silicon band gap. In the presentation, special attention will be paid to mechanistic aspects of electroreduction of carbon dioxide, fabrication and characterization of highly selective and durable semiconductor photoelectrode materials and to importance of the reaction conditions.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2017-01/32/1553

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2017

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6

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Reduced-Graphene-Oxide-Based Hybrid Supports for Platinum Catalysts Active at Low Loadings during Oxygen Reduction

Kulesza, Pawel J ; Dembinska, Beata ; Zoladek, Sylwia ; [et al.]

The Electrochemical Society ; 2018

In: ECS Meeting Abstracts Vol. MA2018-01, No. 40 ( 2018-04-13), p. 2302-2302

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2018-01, No. 40 ( 2018-04-13), p. 2302-2302

Abstract: Hybrid systems composed of the reduced-graphene-oxide supported gold, iridium or bimetallic (AuIr) nanoparticles (at loadings typically below 5 µg cm -2 ) have been considered as active matrices for platinum catalysts utilized at low loadings ( 〈 20 µg cm -2 ) during the reduction of oxygen in mostly acid but also alkaline media. Comparison is made to the analogous systems based on conventional Vulcan carbon carriers. Gold nanoparticles are prepared both by the electrochemical and chemical reductionapproaches in which the pre-reduced Keggin-type phosphomolybdate heteropolyblue species act as the reducing agent for the HAuCl 4 precursor. Polyoxmetallate (PMo 12 O 40 3- ) adsorbates or “capping ligands” tend to stabilize gold (iridium or bimetallic) nanoparticle deposits, facilitate their dispersion and attachment to carbon supports. Indeed, it is apparent from the independent diagnostic voltammetric experiments (in 0.5 mol dm -3 H 2 SO 4 ) that heteropolymolybdates form readily stable adsorbates on nanostructures of gold, irridium and carbon (reduced graphene oxide and Vulcan). It is reasonable to expect that the polyoxometallate-assisted nucleation of gold has occurred in the proximity of oxygenated defects existing on carbon substrates. Under conditions of the electrochemical experiments performed in 0.1 mol dm -3 KOH) the phosphomolybdate adsorbates are removed from the interface because they undergo dissolution and decomposition in alkaline medium. High electrocatalytic activity of the reduced-graphene oxide-supported catalytic systems toward the reduction of oxygen is demonstrated using chronoamperometry and gas-diffusion electrode, in addition to the conventional and rotating ring-disk electrode (RDE) voltammetry. Among important issues is the presence of structural defects existing on poorly organized graphitic structure of reduced graphene oxide (as evident from Raman spectroscopy). When using the reduced graphene oxide carriers for Au (Ir or AuIr) nanostructures together with Pt nanoparticles, the resulting catalytic systems have exhibited typically higher (certainly not lower) O 2 -reduction currents (relative to those recorded at conventional Vulcan-supported Pt at the same loading) in acid medium (0.5 M H 2 SO 4 ). The RDE data are consistent with the lower formation of the hydrogen peroxide intermediate ( 〈 1% at potentials 0.6 V, or lower, vs RHE). Furthermore, the long-term durability of this family of catalysts should be appreciated.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2018-01/40/2302

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2018

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7

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(Invited) Hybrid Materials for Electrocatalytic and Photoelectrochemical Reduction of Carbon Dioxide: Comparison to Their Activity during Oxygen Reduction

Kulesza, Pawel J ; Seta, Ewelina ; Wadas, Anna ; [et al.]

The Electrochemical Society ; 2016

In: ECS Meeting Abstracts Vol. MA2016-01, No. 38 ( 2016-04-01), p. 1928-1928

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2016-01, No. 38 ( 2016-04-01), p. 1928-1928

Abstract: Numerous homogeneous and heterogeneous catalytic systems have been proposed to induce the CO 2 reduction and, depending on reaction conditions (applied potential, strength of the electrolyte, local pH, local concentration of CO 2 and the catalyst applied), various products can be obtained. Because the CO 2 molecule is very stable, its electroreduction would be characterized by large over-potentials. In this respect, behavior of carbon dioxide resembles that of dioxygen. In both cases, the limiting steps involve protonation of the respective species. A crucial problem in designing effective electrocatalytic systems for the reduction of carbon dioxide is the necessity to cope with the another competitive process, namely the simultaneous hydrogen evolution. Mechanisms of reductions of both carbon dioxide and protons are dependent not only on the proton availability and mobility at the electrocatalytic interface but also on the presence the adsorbed hydrogens at the active catalytic sites. In this respect, numerous metallic catalysts (e.g. Cu, Pd, Pt) have been proposed. Alternate approaches to efficient electroreduction of carbon dioxide my refer to utilization of biological systems. Recently, whole cell biocatalysts and microbial electrocatalysts have been considered. Microorganisms can form very stable biofilms well-adhering to different solid surfaces. We propose here a hybrid (biofilm-based organic-inorganic) support or matrix for catalytic (noble metal) nanoparticles. The system was obtained by consecutive deposition of the porous polyaniline-supported bacterial biofilm ( Yersinia enterocolitica ) and multi-walled carbon nanotubes. Although this biofilm does not exhibit appreciable activity toward reduction of carbon dioxide, its structure (while being robust) contains open water channels existing between the bacterial micro-colonies thus permitting unimpeded flow of the aqueous electrolyte. The system’s performance will also be discussed with respect to the oxygen reduction. To appreciate effective reduction of carbon dioxide, instead of conventional Pd nanoparticles, nanosized Pd immobilized within supramolecular assemblies of tridentate Schiff-base ligands or supported onto hybrid biofilm-based matrices have been considered. Reduction of carbon dioxide begins now at less negative potentials and is accompanied by significant enhancement of the CO 2 -reduction current densities. Among important issues are specific interactions between nitrogen coordinating centers and metallic palladium sites. interface. The above activating phenomena will also be verified during oxygen reduction. Through intentional and controlled combination of metal oxide semiconductors, we have been able to drive effectively photo-electrochemical reduction of carbon dioxide. The combination of titanium (IV) oxide (TiO 2 ) and copper (I) oxide (Cu 2 O) has been explored toward the reduction of carbon (IV) oxide (CO 2 ) before and after sunlight illumination. Application of the hybrid system composed of both above-mentioned oxides resulted in high current densities originating from photoelectrochemical reduction of carbon dioxide mostly to methanol (CH 3 OH) as demonstrated upon identification of final products. The role of TiO 2 is not only in stabilizing the interface: the oxide is also expected to prevent the recombination of charge carriers. Possibility of further decoration with traces of the conventional noble-metal-based systems (mentioned above) will be also addressed.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2016-01/38/1928

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

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8

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Electrocatalytic Sensing of Carbon Dioxide, Oxygen and Inert Inorganic Analytes at Network Films of Transition Metal Complexes

Kulesza, Pawel J ; Wadas, Anna ; Ozimek, Weronika ; [et al.]

The Electrochemical Society ; 2016

In: ECS Transactions Vol. 75, No. 17 ( 2016-08-24), p. 75-84

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In: ECS Transactions, The Electrochemical Society, Vol. 75, No. 17 ( 2016-08-24), p. 75-84

Abstract: Nanostructured metallic Pd centers have been generated by electroreduction of Pd II within the coordination architecture of tridentate Schiff-base-ligands. The resulting Pd nanoparticles (diameters, 5-10 nm) are stabilized and activated by ligand nitrogens, and the electrocatalytic system exhibits appreciable activity toward reduction of CO 2 in 0.1 M KHCO 3 (pH=8.8). Comparison has also been made to the behavior of conventional Pd nanoparticles. In addition to low degree of agglomeration and high active surface area of the Schiff-base-ligand-supported Pd nanocenters, specific interactions between electron-donor N-coordination sites and metallic Pd are expected. Furthermore, such Pd catalysts are highly active during reduction of O2 in alkaline medium (0.1 M KOH). Finally, the potent catalytic properties of Pd have been explored to study reduction of highly inert arsenate(V), OAs(OH) 3 , analytes in acid medium (0.5 M H 2 SO 4 ).

Type of Medium: Online Resource

ISSN: 1938-5862 , 1938-6737

URL: Article

DOI: 10.1149/07517.0075ecst

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

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9

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(Invited) Development of Hybrid Structured Materials for Electrocatalytic, Bioelectrocatalytic and Photoelectrochemical Reduction of Carbon Dioxide

Kulesza, Pawel J ; Wadas, Anna ; Seta, Ewelina ; [et al.]

The Electrochemical Society ; 2016

In: ECS Meeting Abstracts Vol. MA2016-02, No. 49 ( 2016-09-01), p. 3689-3689

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2016-02, No. 49 ( 2016-09-01), p. 3689-3689

Abstract: There has been growing interest in the electrochemical reduction of carbon dioxide, a potent greenhouse gas and a contributor to global climate change. Given the fact that the CO 2 molecule is very stable, its electroreduction processes are characterized by large overpotentials. To produce highly efficient and selective electrocatalysts, the transition-metal-based molecular materials are often considered. It is believed that, during electroreduction, the rate limiting step is the protonation of the adsorbed CO product to form the CHO adsorbate. To optimize the hydrogenation-type electrocatalytic approach, we have proposed to utilize nanostructured metallic centers (e.g. Pd, Pt or Ru) in a form of highly dispersed and reactive nanoparticles generated within supramolecular network of distinct nitrogen, sulfur or oxygen-coordination complexes. Reduction of carbon dioxide begins now at less negative potentials and is accompanied by significant enhancement of the reduction current densities. Among important issues are the mutual completion between hydrogen evolution and carbon dioxide reduction and specific interactions between coordinating centers and metallic sites. We have also explored the ability of biofilms to form hydro-gel-type aggregates of microorganisms attached to various surfaces including those of carbon electrode materials. Biofilms are able to transfer electrons to and from electrodes, and they can act in a manner analogous to redox or conducting polymer films on electrodes. Here we have explored a biofilm formed by a strain of Yersinia enterocolitica as active bioelectrocatalytic support; it is characterized by long-term stability over wide ranges of pH (4-10) and temperatures (0-40°C). Upon incorporation of various noble metal nanostructures and/or conducting polymer ultra-thin films, a highly reactive and selective system toward CO 2 -reduction is obtained. Another possibility to enhance electroreduction of carbon dioxide is to explore direct transformation of solar energy to chemical energy using transition metal oxide semiconductor materials. We show here that, by intentional and controlled combination of metal oxide semiconductors, we have been able to drive effectively photoelectrochemical reduction of carbon dioxide. The combination of titanium (IV) oxide and copper (I) oxide has been explored toward the reduction of CO 2 before and after illumination. Application of the hybrid system composed of both oxides has resulted in high current densities originating from photoelectrochemical reduction of carbon dioxide mostly to methanol, as demonstrated upon identification of final products using conventional and mass-spectrometry-assisted gas chromatography. A role of TiO 2 is not only stabilizing: the oxide is also expected to prevent the recombination of charge carriers. Bacterial-biofilm-enhanced photoelectrochemical interfaces for improved reduction of carbon dioxide will also be considered.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2016-02/49/3689

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

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10

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Development of Nanostructured Hybrid Materials for Electrocatalytic and Photoelectrocatalytic Reduction of Carbon Dioxide

Kulesza, Pawel J ; Wadas, Anna ; Szaniawska, Ewelina ; [et al.]

The Electrochemical Society ; 2015

In: ECS Meeting Abstracts Vol. MA2015-02, No. 43 ( 2015-07-07), p. 1708-1708

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In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2015-02, No. 43 ( 2015-07-07), p. 1708-1708

Abstract: There has been growing interest in the electrochemical reduction of carbon dioxide (CO 2 ), a potent greenhouse gas and a contributor to global climate change, and its conversion into useful carbon-based fuels or chemicals. Numerous homogeneous and heterogeneous catalytic systems have been proposed to induce the CO 2 reduction and, depending on the reaction conditions various products that include carbon monoxide, oxalate, formate, carboxylic acids, formaldehyde, acetone or methanol, in addition to various hydrocarbons at different ratios. Given the fact that the CO 2 molecule is very stable, its electroreduction processes are characterized by large overpotentials. To produce highly efficient and selective electrocatalysts, the transition-metal-based molecular materials are often considered. It is believed that, during electroreduction, the rate limiting step is the protonation of the adsorbed CO product to form the CHO adsorbate. Because reduction of CO 2 can effectively occur by hydrogenation, to optimize the conventional electrocatalytic approach, we propose such a model catalytic system as nanostructured metallic palladium capable of absorbing reactive hydrogen in addition to the ability to adsorb monoatomic hydrogen at the interface. Under such conditions, the two-electron reduction of CO 2 typically to CO is favored. To produce highly dispersed and reactive nanoparticles, we generate them by electrodeposition from N-coordination complexes of palladium(II). The resulting metallic Pd nanoparticles, rather than Pd cationic species, are stabilized and activated by nitrogen coordination centers from the macromolecular matrix. In the present research, we demonstrate that stabilization and activation of highly dispersed nanostructured metallic Pd centers with a supramolecular architecture of “privileged ligands” results in the electrocatalytic enhancement of the CO 2 reduction. Reduction of carbon dioxide begins now at less negative potentials and is accompanied by significant enhancement of the CO 2 -reduction current densities. Among important issues are specific interactions between nitrogen coordinating centers and metallic palladium sites at the electrocatalytic interface. Another possibility to enhance electroreduction of carbon dioxide is to explore direct transformation of solar energy to chemical energy using transition metal oxide semiconductor materials. We show here that, by intentional and controlled combination of metal oxide semiconductors, we have been able to drive effectively photoelectrochemical reduction of carbon dioxide. The combination of titanium (IV) oxide (TiO 2 ) and copper (I) oxide (Cu 2 O) has been explored toward the reduction of carbon (IV) oxide (CO 2 ) before and after sunlight illumination. Application of the hybrid system composed of both above-mentioned oxides resulted in high current densities originating from photoelectrochemical reduction of carbon dioxide mostly to methanol (CH 3 OH), as demonstrated upon identification of final products using conventional and mass-spectrometry assisted gas chromatography. On mechanistic grounds, the role of TiO 2 seems to be not only stabilizing: the oxide is also expected to prevent the recombination of charge carriers.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2015-02/43/1708

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2015

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