Your search keyword '"oxygen-evolving catalyst"' showing total 6 results

1. Rational Design Combining Morphology and Charge-Dynamic for Hematite/Nickel–Iron Oxide Thin-Layer Photoanodes: Insights into the Role of the Absorber/Catalyst Junction

Author

Nainesh Patel, Michele Orlandi, Francesco Nart, Rita Boaretto, Antonio Miotello, A. Mazzi, Stefano Caramori, Carlo Alberto Bignozzi, Serena Berardi, and Nicola Bazzanella

Subjects

Materials science, Oxide, thin-layer photoanode, oxygen-evolving catalyst, pulsed laser deposition, porous morphology, photoelectrosynthesis, adaptive junction, nickel iron oxide, impedance spectroscopy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, photoelectrosynthesis, Pulsed laser deposition, Artificial photosynthesis, chemistry.chemical_compound, General Materials Science, pulsed laser deposition, Photocurrent, adaptive junction, impedance spectroscopy, porous morphology, business.industry, Ambientale, nickel iron oxide, Hematite, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Amorphous solid, Dielectric spectroscopy, Semiconductor, oxygen-evolving catalyst, Chemical engineering, chemistry, thin-layer photoanode, visual_art, visual_art.visual_art_medium, 0210 nano-technology, business

Abstract

Water oxidation represents the anodic reaction in most of the photoelectrosynthetic setups for artificial photosynthesis developed so far. The efficiency of the overall process strongly depends on the joint exploitation of good absorber domains and interfaces with minimized recombination pathways. To this end, we report on the effective coupling of thin-layer hematite with amorphous porous nickel-iron oxide catalysts prepared via pulsed laser deposition. The rational design of such composite photoelectrodes leads to the formation of a functional adaptive junction, with enhanced photoanodic properties with respect to bare hematite. Electrochemical impedance spectroscopy has contributed to shed light on the mechanisms of photocurrent generation, confirming the reduction of recombination pathways as the main contributor to the improved performances of the functionalized photoelectrodes. Our results highlight the importance of the amorphous catalysts' morphology, as dense and electrolyte impermeable layers hinder the pivotal charge compensation processes at the interface. The direct comparison with all-iron and all-nickel catalytic counterparts further confirms that control over the kinetics of both hole transfer and charge recombination, enabled by the adaptive junction, is key for the optimal operation of this kind of semiconductor/catalyst interfaces.

Published

2019

2. Photoelectrochemical Performance of the Ag(III)-Based Oxygen-Evolving Catalyst

Author

Manuel Ghibaudo, Claudio Minero, and Fabrizio Sordello

Subjects

Materials science, Inorganic chemistry, 02 engineering and technology, 010402 general chemistry, Electrosynthesis, water splitting, 01 natural sciences, hematite, Artificial photosynthesis, law.invention, Catalysis, artificial photosynthesis, oxygen-evolving catalyst, silver oxide, TiO2, Materials Science (all), law, General Materials Science, Bulk electrolysis, Electrolysis, Oxygen evolution, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Catalytic oxidation, Water splitting, 0210 nano-technology

Abstract

We report the electrosynthesis of a water oxidation catalyst based on Ag oxides (AgCat). The deposited AgCat is composed of mixed valence crystalline Ag oxides with the presence of particle aggregates whose size is ∼1 μm. This catalyst, coupled with TiO2 and hematite, and under photoelectrochemical conditions, substantially increases photocurrents in a wide range of applied potentials compared with bare and Co-Pi-modified photocatalysts. AgCat can sustain current densities comparable with other water oxidation catalysts. Dark bulk electrolysis demonstrated that AgCat is stable and can sustain high turnover number in operative conditions. Oxygen evolution from water occurs in mild conditions: pH = 2–13, room temperature and pressure, and moderate overpotentials (600 mV) compatible with the coupling with semiconducting oxides as sensitizers. Using hematite in sustained electrolysis O2 production is significant, both in the dark and under irradiation, after an initial slow induction time in which modificatio...

Published

2017

3. A first principles study of water oxidation catalyzed by a tetraruthenium-oxo core embedded in polyoxometalate ligands

Author

Simone Piccinin and Stefano Fabris

Subjects

Reaction mechanism, 010405 organic chemistry, Chemistry, General Physics and Astronomy, Reaction intermediate, Overpotential, 010402 general chemistry, Oxygen-evolving catalyst, 7. Clean energy, 01 natural sciences, Electrolysis, Settore FIS/03 - Fisica della Materia, 0104 chemical sciences, Catalysis, Electron transfer, Catalytic cycle, Polyoxometalate, Physical chemistry, Density functional theory, Physical and Theoretical Chemistry

Abstract

We present a computational study addressing the catalytic cycle of a recently-synthesized all-inorganic homogeneous catalyst capable to promote water oxidation with low overpotential and high turnover frequency [Sartorel et al., J. Am. Chem. Soc., 2008, 130, 5006; Geletii et al., Angew. Chem., Int. Ed., 2008, 47, 3896]. This catalyst consists of a tetraruthenium-oxo core [Ru(4)O(4)(OH)(2)·(H(2)O)(4)](6+)capped by two polyoxometalate [SiW(10)O(36)](8-) units. The reaction mechanism underpinning its efficiency is currently under debate. We study a reaction cycle involving four consecutive proton-coupled electron transfer (PCET) processes that successively oxidize the four Ru(IV)-H(2)O units of the initial state (S(0)) to the four Ru(V)-OH centers of the activated intermediate (S(4)). The energetics of these electrochemical processes as well as the structural and electronic properties of the reaction intermediates are studied with ab initio Density Functional Theory (DFT) calculations. After characterizing these reaction intermediates in the gas phase, we show that the solvated tetraruthenate core undergoes a solvent-induced structural distortion that brings the predicted molecular geometry to excellent agreement with the experimental X-ray diffraction data. The calculated electronic properties of the catalyst are instead weakly dependent on the presence of the solvent. The frontier orbitals of the initial state as well as the electronic states involved in the PCET steps are shown to be localized on the tetraruthenium-oxo core. The reaction thermodynamics predicted for the intermediate reaction steps is in good agreement with the available cyclic voltammetry measurements up to S(3), but the calculated free energy difference between the initial and the activated state (S(0)/S(4)) turns out to be significantly lower than the thermodynamic limit for water oxidation. Since the oxidizing power of the S(0)/S(4) couple is not sufficient to split water, we suggest that promoting this reaction would require cycling between higher oxidation states.

Published

2011

4. Nanocrystalline Boron-Doped Diamond as a Corrosion-Resistant Anode for Water Oxidation via Si Photoelectrodes

Author

Ashcheulov, Petr, Taylor, Andrew, Mortet, Vincent, Poruba, Ales, Le Formal, Florian, Krysova, Hana, Klementova, Mariana, Hubik, Pavel, Kopecek, Jaromir, Lorincik, Jan, Yum, Jun-Ho, Kratochvilova, Irena, Kavan, Ladislav, and Sivula, Kevin

Subjects

semiconducting photoanodes, nanocrystalline diamond, chemical-vapor-deposition, photoanode, water splitting, fuel generators, electrodes, thin-film, oxygen-evolving catalyst, polycrystalline diamond, protective coating transparent conductive film, electrocatalytic properties, silicon photoelectrodes, solar hydrogen-production, silicon photoanodes

Abstract

Due to its high sensitivity to corrosion, the use of Si in direct photoelectrochemical (PEC) water-splitting systems that convert solar energy into chemical fuels has been greatly limited. Therefore, the development of low-cost materials resistant to corrosion under oxidizing conditions is an important goal toward a suitable protection of otherwise unstable semiconductors used in PEC cells. Here, we report on the development of a protective coating based on thin and electrically conductive nanocrystalline boron-doped diamond (BDD) layers. We found that BDD layers protect the underlying Si photoelectrodes over a wide pH range (1-14) in aqueous electrolyte solutions. A BDD layer maintains an efficient charge carrier transfer from the underlying silicon to the electrolyte solution. SiIBDD photo electrodes show no sign of performance degradation after a continuous PEC treatment in neutral, acidic, and basic electrolytes. The deposition of a cobalt phosphate (CoPi) oxygen evolution catalyst onto the BDD layer significantly reduces the overpotential for water oxidation, demonstrating the ability of BDD layers to substitute the transparent conductive oxide coatings, such as indium tin oxide (ITO) and fluorine-doped tin oxide (FTO), frequently used as protective layers in Si photoelectrodes.

5. Strategies for Semiconductor/Electrocatalyst Coupling toward Solar-Driven Water Splitting

Author

Thalluri, Sitaramanjaneya Mouli, Bai, Lichen, Lv, Cuncai, Huang, Zhipeng, Hu, Xile, and Liu, Lifeng

Subjects

atomic-layer deposition, electroless deposition, surface recombination, photoelectrochemical hydrogen-production, photoelectrochemical water splitting, chemical-vapor-deposition, electrocatalysts, bivo4 photoelectrodes, oxygen-evolving catalyst, doped hematite photoanode, coupling strategies, molybdenum sulfide catalyst, silicon nanowire arrays, semiconductor photoelectrodes

Abstract

Hydrogen (H-2) has a significant potential to enable the global energy transition from the current fossil-dominant system to a clean, sustainable, and low-carbon energy system. While presently global H-2 production is predominated by fossil-fuel feedstocks, for future widespread utilization it is of paramount importance to produce H-2 in a decarbonized manner. To this end, photoelectrochemical (PEC) water splitting has been proposed to be a highly desirable approach with minimal negative impact on the environment. Both semiconductor light-absorbers and hydrogen/oxygen evolution reaction (HER/OER) catalysts are essential components of an efficient PEC cell. It is well documented that loading electrocatalysts on semiconductor photoelectrodes plays significant roles in accelerating the HER/OER kinetics, suppressing surface recombination, reducing overpotentials needed to accomplish HER/OER, and extending the operational lifetime of semiconductors. Herein, how electrocatalyst coupling influences the PEC performance of semiconductor photoelectrodes is outlined. The focus is then placed on the major strategies developed so far for semiconductor/electrocatalyst coupling, including a variety of dry processes and wet chemical approaches. This Review provides a comprehensive account of advanced methodologies adopted for semiconductor/electrocatalyst coupling and can serve as a guideline for the design of efficient and stable semiconductor photoelectrodes for use in water splitting.

6. The Role of Cobalt Phosphate in Enhancing the Photocatalytic Activity of alpha-Fe2O3 toward Water Oxidation

Author

Barroso, Monica, Cowan, Alexander J., Pendlebury, Stephanie R., Graetzel, Michael, Klug, David R., and Durrant, James R.

Subjects

Nanostructured Alpha-Fe2O3, Neutral Ph, Evolution, Progress, Oxide, Photooxidation, Photoanodes, Spectroscopy, Oxygen-Evolving Catalyst, Films

Abstract

Transient absorption spectroscopy was used to probe the dynamics of photogenerated charge carriers in alpha-Fe2O3/CoOx nanocomposite photoelectrodes for water splitting. The addition of cobalt-based electrocatalysts was observed to increase the lifetime of photogenerated holes in the photoelectrode by more than 3 orders of magnitude without the application of electrical bias. We therefore propose that the enhanced photoelectrochemical activity of the composite electrode for water photooxidation results, at least in part, from reduced recombination losses because of the formation of a Schottky-type heterojunction.