Search results for "Anodizing"

showing 10 items of 116 documents

Photoelectrocatalyzed degradation of organophosphorus pesticide fenamiphos using WO3 nanorods as photoanode

2020

[EN] In this study, WO3 nanostructures were synthesized by the electrochemical anodization technique to use them on the degradation of persistent organic compounds such as the pesticide fenamiphos. The acids electrolyte used during the anodization were two different: 1.5 M H2SO4-0.05 M H2O2 and 1.5 M CH4O3S-0.05 M H2O2. Once the samples have been manufactured, they have been subjected to different tests to analyze the properties of the nanostructures. With Field Emission Scanning Electron Microscopy (FESEM) the samples have been examined morphologically, their composition and crystallinity has been studied through Raman Spectroscopy and their photoelectrochemical behaviour by Photoelectroch…

InsecticidesEnvironmental EngineeringMaterials scienceHealth Toxicology and Mutagenesis0208 environmental biotechnology02 engineering and technologyElectrolyte010501 environmental sciences01 natural sciencesINGENIERIA QUIMICAchemistry.chemical_compoundCrystallinitysymbols.namesakeDegradationEnvironmental ChemistryFenamiphos0105 earth and related environmental sciencesNanoestructuresWO3 nanostructureAnodizingPublic Health Environmental and Occupational HealthGeneral MedicineGeneral ChemistryPollution020801 environmental engineeringDielectric spectroscopyPesticideChemical engineeringchemistrysymbolsDegradation (geology)NanorodPhotoelectrocatalysisRaman spectroscopyFenamiphos
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Bioactivity Performance of Pure Mg after Plasma Electrolytic Oxidation in Silicate-Based Solutions

2021

The biodegradable metals, including magnesium (Mg), are a convenient alternative to permanent metals but fast uncontrolled corrosion limited wide clinical application. Formation of a barrier coating on Mg alloys could be a successful strategy for the production of a stable external layer that prevents fast corrosion. Our research was aimed to develop an Mg stable oxide coating using plasma electrolytic oxidation (PEO) in silicate-based solutions. 99.9% pure Mg alloy was anodized in electrolytes contained mixtures of sodium silicate and sodium fluoride, calcium hydroxide and sodium hydroxide. Scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDX), contact angle (CA), …

LuminescencePlasma GasesPharmaceutical ScienceSodium silicate02 engineering and technologymagnesium01 natural sciencesdegradation rateAnalytical Chemistrychemistry.chemical_compoundCoated Materials BiocompatibleCoatingDrug DiscoveryMagnesiumPhosphorusPlasma electrolytic oxidation021001 nanoscience & nanotechnologyAnti-Bacterial AgentsBody FluidsSolutionsChemistry (miscellaneous)Sodium hydroxideMolecular Medicine0210 nano-technologyOxidation-ReductionStaphylococcus aureusMaterials scienceplasma electrolytic oxidationCell SurvivalOxidechemistry.chemical_elementMicrobial Sensitivity Testsengineering.material010402 general chemistryElectrolysisArticleCorrosionlcsh:QD241-441biocompatibilitylcsh:Organic chemistryCell Line TumorHumansPhysical and Theoretical Chemistryantibacterial propertiesElectrodesAnodizingSilicatesOrganic ChemistrySpectrometry X-Ray Emission0104 chemical sciencessilicate bathchemistryengineeringCalciumNuclear chemistryMolecules
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Behavior of alloying elements during anodizing of Mg-Cu and Mg-W alloys in a fluoride/glycerol electrolyte

2015

Anodizing of sputtering-deposited magnesium and Mg-0.75at.%Cu and Mg-1.23at.%W alloys has been carried out in a fluoride/ glycerol electrolyte. The aims of the study were to investigate the enrichment of alloying elements in the alloy immediately beneath the anodic film and the migration of alloying element species in the film. The specimens were examined by electron microscopy and ion beam analysis. An enrichment of copper is revealed in the Mg-Cu alloy that increases with the anodizing time up to ∼6×1015 Cu atoms cm-2. Copper species are then incorporated into the anodic film and migrate outwards. In contrast, no enrichment of tungsten occurs in the Mg-W alloy, and tungsten species are im…

Materials Chemistry2506 Metals and Alloy/dk/atira/pure/subjectarea/asjc/2100/2105/dk/atira/pure/subjectarea/asjc/2500/2508Materials scienceAnodizing/dk/atira/pure/subjectarea/asjc/2500/2505Renewable Energy Sustainability and the EnvironmentElectronic Optical and Magnetic Material/dk/atira/pure/subjectarea/asjc/2500/2504Inorganic chemistry/dk/atira/pure/subjectarea/asjc/3100/3104Surfaces Coatings and FilmElectrolyteElectrochemistryCondensed Matter PhysicsElectronic Optical and Magnetic MaterialsSurfaces Coatings and Filmschemistry.chemical_compoundSettore ING-IND/23 - Chimica Fisica ApplicatachemistryGlycerolElectrochemistryMaterials ChemistryFluoride/dk/atira/pure/subjectarea/asjc/1600/1603
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Anodizing of aluminium and AA 2024-T3 alloy in chromic acid: Effects of sulphate on film growth

2017

Chromic acid anodizing is important for the corrosion protection of aerospace aluminium alloys. Previous study has demonstrated that SO42 − impurity in the chromic acid affects the film growth on aluminium at a voltage of 100 V. The present work further investigates aluminium and extends the study to industrial anodizing conditions (Bengough-Stuart (B-S) process) and to the AA 2024-T3 alloy. It is shown that SO42 − concentrations between ~ 38–300 ppm reduce the film growth rate for aluminium anodized at 100 V in comparison with an electrolyte than contains ≤ 1.5 ppm SO42 −, whereas ~ 1500–3000 ppm SO42 have an opposite effect and lead to an unstable pore diameter. Under the B-S process, the…

Materials Chemistry2506 Metals and AlloysChemistry(all)AA 2024 alloyChemistry (all)Surfaces Coatings and FilmChromic acidSurfaces and InterfacesCondensed Matter PhysicAnodizingSulphateCondensed Matter PhysicsSurfaces Coatings and FilmsSettore ING-IND/23 - Chimica Fisica ApplicataMaterials ChemistryAluminiumSurfaces and Interface
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Physico-Chemical Characterization of Anodic Oxides on Hf as a Function of the Anodizing Conditions

2016

Anodic films were grown to 5 V (Ag/AgCl) on mechanically polished Hf in 0.1 M ammonium biborate and 0.1 M NaOH. Independent of the anodizing conditions, the photoelectrochemical characterization allowed the observation of optical transitions at 3.25 eV, i.e. at photon energy lower than the bandgap of HfO2. They are attributed to localized states inside the gap of the oxide induced by the presence of oxygen vacancies. From the cathodic photocurrent spectra, it was possible to estimate an energy threshold of ∼2.15 eV for internal electron photoemission phenomena. The impedance measurements proved the formation of insulating oxides with ϵ =19. The anodizing occurs under a high field regime wit…

Materials Chemistry2506 Metals and AlloysMaterials scienceRenewable Energy Sustainability and the EnvironmentAnodizingElectronic Optical and Magnetic MaterialMetallurgySurfaces Coatings and FilmCondensed Matter Physic02 engineering and technologyFunction (mathematics)010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciences0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsCharacterization (materials science)AnodeSettore ING-IND/23 - Chimica Fisica ApplicataMaterials ChemistryElectrochemistry0210 nano-technologyJournal of The Electrochemical Society
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Novel TiO2-WO3 self-ordered nanotubes used as photoanodes: Influence of Na2WO4 and H2O2 concentration during electrodeposition

2021

[EN] Hybrid TiO2-WO3 nanostructures has been synthesized by electrochemical anodization under controlled hydrodynamic conditions followed by electrodeposition in the presence of different contents of Na2WO4 (5, 15 and 25 mM) and H2O2 (20, 30 and 40 mM). The influence of the electrolyte used for electrodeposition on the morphology, crystalline structure and photoelectrochemical response for water splitting has been evaluated through Field Emission Electronic Microscopy, High-Resolution Transmission Electron Microscopy, Confocal Raman Spectroscopy, Grazing Incidence X Ray Diffraction, X-Ray Photoelectron Spectroscopy, Atomic Force microscopy and photocurrent versus potential measurements. Add…

Materials science02 engineering and technologyElectrolyte010402 general chemistry01 natural sciencesINGENIERIA QUIMICAX-ray photoelectron spectroscopyElectrodepositionMaterials ChemistryTiO2-WO3 nanostructuresWater splittingPhotocurrentAnodizingHeterojunctionSurfaces and InterfacesGeneral Chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics0104 chemical sciencesSurfaces Coatings and FilmsField electron emissionChemical engineeringTransmission electron microscopyWater splittingPhotoelectrocatalysisAnodization0210 nano-technology
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Electrochemically etched sharp aluminium probes with nanoporous aluminium oxide coatings: demonstration of addressed DNA delivery

2014

Electrochemical etching of metal wires is widely used to fabricate sharp probes for use in scanning tunnelling microscopy. In this work an electrochemical fabrication method for sharp aluminium probes coated with nanoporous anodised aluminium oxide (AAO) layer is described. The method presented here involves simultaneous anodisation and etching of aluminium wires. The probe apex radius as well as the nanopore length and diameter depend on the etching mode, which could be direct current (DC), alternating current (AC), or pulsed voltage mode (PVM). The probes, coated with a nanoporous AAO layer, were used to demonstrate addressed DNA delivery.

Materials science:NATURAL SCIENCES::Chemistry [Research Subject Categories]AnodizingNanoporousGeneral Chemical EngineeringOxidechemistry.chemical_elementNanotechnologyGeneral ChemistryNanoporechemistry.chemical_compoundchemistryEtching (microfabrication)AluminiumAluminium oxideLayer (electronics)RSC Adv.
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2017

Abstract Chromic acid anodizing is important for the corrosion protection of aerospace aluminium alloys. Previous study has demonstrated that SO 4 2 − impurity in the chromic acid affects the film growth on aluminium at a voltage of 100 V. The present work further investigates aluminium and extends the study to industrial anodizing conditions (Bengough-Stuart (B-S) process) and to the AA 2024-T3 alloy. It is shown that SO 4 2 − concentrations between ~ 38–300 ppm reduce the film growth rate for aluminium anodized at 100 V in comparison with an electrolyte than contains ≤ 1.5 ppm SO 4 2 − , whereas ~ 1500–3000 ppm SO 4 2 have an opposite effect and lead to an unstable pore diameter. Under th…

Materials scienceAlloychemistry.chemical_element02 engineering and technologyengineering.material010402 general chemistry01 natural sciencesCorrosionchemistry.chemical_compoundAluminiumMaterials Chemistry5052 aluminium alloyChromate conversion coatingAnodizingMetallurgySurfaces and InterfacesGeneral Chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics0104 chemical sciencesSurfaces Coatings and FilmschemistryChromic acidengineering6063 aluminium alloy0210 nano-technologySurface and Coatings Technology
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Influence of Anodic and Thermal Barrier Layers on Physicochemical Behavior of Anodic TiO2 Nanotubes

2011

Electrochemical and photo-electrochemical behavior of self-organized TiO2 nanotubes formed in organic solvents have been studied by taking into account the formation of new barrier layers beneath nanotubes either due to the anodic polarization in aqueous solutions or air exposure during high temperature annealing. It has been shown that before annealing, electrochemical and photoelectrochemical answers are dominantly controlled by the physicochemical properties of the anodic barrier layer. Annealing in air at sufficiently high temperatures changes the initial amorphous structure of as-prepared nanotubes and forms a new oxide layer below them due to thermal oxidation of underneath titanium. …

Materials scienceAnnealing (metallurgy)Oxidechemistry.chemical_elementNanotechnologyTiO2 nanotubeThermal barrier coatingBarrier layerchemistry.chemical_compoundPhotoelectrochemistryMaterials ChemistryElectrochemistryPolarization (electrochemistry)Thermal oxidationElectrochemical Impedance MeasurementRenewable Energy Sustainability and the EnvironmentAnodizingSEM.Condensed Matter PhysicsSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsSettore ING-IND/23 - Chimica Fisica ApplicatachemistryChemical engineeringanodizingTitanium
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Photoelectrochemical removal of chlorfenvinphos by using WO3 nanorods: Influence of annealing temperature and operation pH

2019

[EN] A visible-light driven photoelectrochemical degradation process has been applied to a solution polluted with the organophosphate insecticide chlorfenvinphos. Different WO3 nanosheets/nanorods have been used as photoanodes. These nanostructured electrodes have been fabricated by anodization of tungsten and, subsequently, they have been subjected to a thermal treatment (annealing). The combined influence of annealing temperature (400¿°C and 600¿°C) and operation pH (1 and 3) on the photoelectrocatalytic behavior of these nanorods has been examined through a statistical analysis. Morphological, structural and photoelectrochemical characterizations have also been carried out. The chlorfenv…

Materials scienceAnnealing (metallurgy)Regression modelKineticschemistry.chemical_elementFiltration and Separation02 engineering and technologyThermal treatmentTungstenINGENIERIA QUIMICAAnalytical Chemistrychemistry.chemical_compound020401 chemical engineeringPhotoelectrochemical degradationWO3 nanorods0204 chemical engineeringAnodizingNanotecnologiaChlorfenvinphosChlorfenvinphos021001 nanoscience & nanotechnologyElectroquímicaChemical engineeringchemistryElectrodeNanorodAnodization0210 nano-technology
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