Search results for " nanostructure"

showing 10 items of 175 documents

Biosynthesis of selenium-nanoparticles and -nanorods as a product of selenite bioconversion by the aerobic bacterium Rhodococcus aetherivorans BCP1

2018

The wide anthropogenic use of selenium compounds represents the major source of selenium pollution world- wide, causing environmental issues and health concerns. Microbe-based strategies for metal removal/recovery have received increasing interest thanks to the association of the microbial ability to detoxify toxic metal/ metalloid polluted environments with the production of nanomaterials. This study investigates the tolerance and the bioconversion of selenite (SeO32−) by the aerobically grown Actinomycete Rhodococcus aetherivorans BCP1 in association with its ability to produce selenium nanoparticles and nanorods (SeNPs and SeNRs). The BCP1 strain showed high tolerance towards SeO32− with…

0301 basic medicineBioconversionStatic Electricity030106 microbiologychemistry.chemical_elementBioengineeringSelenious AcidSettore BIO/19 - Microbiologia GeneraleSelenium pollutionSelenium03 medical and health sciencesMinimum inhibitory concentrationchemistry.chemical_compoundNanoparticleBiosynthesisRhodococcusParticle SizeSelenite Rhodococcus aetherivorans Selenium nanoparticles Selenium nanorods Biogenic nanostructuresSelenium nanorodMolecular BiologyNanotubesbiologyBiogenic nanostructureRhodococcus aetherivoranSpectrometry X-Ray EmissionGeneral Medicinebiology.organism_classificationDynamic Light ScatteringSelenium nanoparticleBacteria AerobicNanotube030104 developmental biologychemistryBiochemistry13. Climate actionSelenious AcidSeleniteNanoparticlesMetalloidRhodococcusSeleniumRhodococcuBiotechnologyNew Biotechnology
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Rhodococcus aetherivorans BCP1 as cell factory for the production of intracellular tellurium nanorods under aerobic conditions

2016

Tellurite (TeO3 2−) is recognized as a toxic oxyanion to living organisms. However, mainly anaerobic or facultative-anaerobic microorganisms are able to tolerate and convert TeO3 2− into the less toxic and available form of elemental Tellurium (Te0), producing Te-deposits or Te-nanostructures. The use of TeO3 2−-reducing bacteria can lead to the decontamination of polluted environments and the development of “green-synthesis” methods for the production of nanomaterials. In this study, the tolerance and the consumption of TeO3 2− have been investigated, along with the production and characterization of Te-nanorods by Rhodococcus aetherivorans BCP1 grown under aerobic conditions. Aerobically …

0301 basic medicineMicroorganism030106 microbiologyOxyanionBioengineeringSettore BIO/19 - Microbiologia GeneraleApplied Microbiology and Biotechnology03 medical and health scienceschemistry.chemical_compoundMinimum inhibitory concentrationBiogenic nanostructuresTelluriteRhodococcusFood scienceTellurium nanorodsSettore CHIM/02 - Chimica FisicaNanorods biosynthesisNanotubesbiologyStrain (chemistry)ResearchBiogenic nanostructureNanorods biosynthesiAerobiosiRhodococcus aetherivoranElemental telluriumTellurium nanorodbiology.organism_classificationAerobiosisNanotubeRhodococcus aetherivoranschemistryBiochemistryTelluriumAnaerobic exerciseRhodococcusBacteriaIntracellularRhodococcuBiotechnology
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Non-conventional Ce:YAG nanostructures via urea complexes

2019

AbstractCe:YAG nanostructures (Ce:YAG = Cerium in Yttrium Aluminium Garnet), easy to control and shape, have been prepared via templating approach using natural and synthetic materials (i.e. paper, cotton wool and glass wool) previously soaked with a gel-like metals precursor and then thermally treated to achieve the wished morphology. The final material, otherwise difficult to process, can be easily moulded, it is lightweight, portable and forms, at the nanoscale, homogeneous layers of interconnected but not agglomerated nanoparticles (15 ± 5 nm). Using the same synthetic route, called Urea-Glass-Route, but in absence of a template, extremely pure Ce:YAG nanoparticle (45 ± 5 nm) can be als…

0301 basic medicineMultidisciplinaryMaterials scienceNanostructureYAG Glass Wool nanostructuresDopinglcsh:RNanoparticlelcsh:MedicineGlass woolDurabilityArticle03 medical and health scienceschemistry.chemical_compound030104 developmental biology0302 clinical medicineChemical engineeringchemistryYttrium aluminium garnetlcsh:Qlcsh:ScienceNanoscopic scaleScaling030217 neurology & neurosurgerySettore CHIM/02 - Chimica Fisica
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Ni-Based Alloy Nanostructured Electrodes for Alkaline Electrolyzers

In water alkaline electrolyzer field, the development of Nickel-based nanostructured electrode is one of the possible ways to improve the water electrolysis efficiency

Alkaline Electrolyzer Nanostructured Electrodes Ni-Co Alloy Ni-W alloy Ni-Zn alloy Template ElectrosynthesisSettore ING-IND/23 - Chimica Fisica ApplicataSettore ING-IND/17 - Impianti Industriali Meccanici
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Amorphous Silicon Nanotubes via Galvanic Displacement Deposition

2013

Amorphous silicon nanotubes were grown in a single step into a polycarbonate membrane by a galvanic displacement reaction conducted in aqueous solution. In order to optimize the process, a specifically designed galvanic cell was used. SEM images, after polycarbonate dissolution, showed interconnected nanotube bundles with an average length of 18 μm and wall thickness of 38 nm.The deposited silicon was revealed by EDS analysis, whilst X-ray diffraction and Raman spectroscopy showed that nanotubes have an amorphous structure. Silicon nanotubes were also characterized by photo-electrochemical measurements that showed n-type conductivity and optical gap of ~1.6 eV. Keywords: Silicon nanotubes, …

Amorphous siliconSilicon nanotubes dispalcement deposition nanostructures lithium batteries solar cellsNanotubeMaterials scienceSiliconNanocrystalline siliconchemistry.chemical_elementNanotechnologyAmorphous solidlcsh:Chemistrysymbols.namesakechemistry.chemical_compoundSettore ING-IND/23 - Chimica Fisica Applicatalcsh:Industrial electrochemistrylcsh:QD1-999chemistryvisual_artElectrochemistrysymbolsvisual_art.visual_art_mediumGalvanic cellPolycarbonateComposite materialRaman spectroscopylcsh:TP250-261
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Core-shell Zn-doped TiO2-ZnO nanofibers fabricated via a combination of electrospinning and metal-organic chemical vapour deposition

2010

Zn-doped TiO2 nanofibers shelled with ZnO hierarchical nanoarchitectures have been fabricated combining electrospinning of TiO2 (anatase) nanofibers and metal-organic chemical vapor deposition (MOCVD) of ZnO. The proposed hybrid approach has proven suitable for tailoring both the morphology of the ZnO external shell as well as the crystal structure of the Zn-doped TiO2 core. It has been found that the Zn dopant is incorporated in calcined electrospun nanofibers without any evidence of ZnO aggregates. Effects of different Zn doping levels of Zn-doped TiO2 fibers have been scrutinized and morphological, structural, physico-chemical and optical properties evaluated before and after the hierarc…

AnataseMaterials scienceSettore ING-IND/22 - Scienza e Tecnologia dei MaterialiNanotechnologyCathodoluminescenceChemical vapor depositionNANOWIRESNANOSTRUCTURESZN-DOPINGTITANIA; ELECTROSPINNING; NANOFIBERS; CHEMICAL VAPOUR DEPOSITION ZN-DOPINGROUTEXPSGeneral Materials ScienceMetalorganic vapour phase epitaxyZINC-OXIDENanocompositeDopantELECTROSPINNINGPHOTOCATALYTIC ACTIVITYGeneral ChemistryOPTICAL-PROPERTIESCondensed Matter PhysicsNANOCOMPOSITESElectrospinningCHEMICAL VAPOUR DEPOSITIONNanofiberTITANIAPHOTOLUMINESCENCESENSITIZED SOLAR-CELLSSENSITIZED SOLAR-CELLS; ZINC-OXIDE; PHOTOCATALYTIC ACTIVITY; OPTICAL-PROPERTIES; PHOTOLUMINESCENCE; NANOSTRUCTURES; NANOCOMPOSITES; NANOWIRES; ROUTE; XPSNANOFIBERS
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Original Approach to Synthesize TiO2/ZnO Hybrid Nanosponges Used as Photoanodes for Photoelectrochemical Applications

2021

[EN] In the present work, TiO2/ZnO hybrid nanosponges have been synthesized for the first time. First, TiO2 nanosponges were obtained by anodization under hydrodynamic conditions in a glycerol/water/NH4F electrolyte. Next, in order to achieve the anatase phase of TiO2 and improve its photocatalytic behaviour, the samples were annealed at 450 degrees C for 1 h. Once the TiO2 nanosponges were synthesized, TiO2/ZnO hybrid nanosponges were obtained by electrodeposition of ZnO on TiO2 nanosponges using different temperatures, times, and concentrations of zinc nitrate (Zn(NO3)(2)). TiO2/ZnO hybrid nanosponges were used as photoanodes in photoelectrochemical water splitting tests. The results indi…

AnataseTechnologyMaterials scienceHybrid nanostructureshybrid nanostructuresNanospongeINGENIERIA QUIMICAArticlechemistry.chemical_compoundsymbols.namesakeX-ray photoelectron spectroscopyZinc nitrateZinc oxideGeneral Materials ScienceMicroscopyQC120-168.85Anodizingtitanium dioxidephotoelectrochemical water splittingTQH201-278.5zinc oxideEngineering (General). Civil engineering (General)TK1-9971chemistryChemical engineeringDescriptive and experimental mechanicsTitanium dioxidePhotocatalysissymbolsTitanium dioxideWater splittingElectrical engineering. Electronics. Nuclear engineeringTA1-2040Raman spectroscopyPhotoelectrochemical water splittingnanospongeMaterials
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Anodic Alumina Membranes for Fuel Cell Technology and Nanostructure Template -assisted Deposition

2009

Anodic Alumina Membranes Fuel Cell Nanostructure
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Structural Characterization of Zirconia Nanoparticles Prepared by Microwave-Hydrothermal Synthesis

2009

Nanocrystalline zirconia powders have been prepared by microwave-hydrothermal synthesis starting from aqueous solution of ZrOCl2·8H2O. Results of investigations on the aqueous suspension stability of the washed zirconia nanopowders by dynamic light scattering showed that the suspension, constituted by superaggregates of nanoparticles (131 ± 10 nm), was stable up to 15 days. Nanopowders were investigated by means of transmission electron microscopy and small angle x-ray scattering measurements which proved that the zirconia nanopowder is constituted by small primary nanoparticles of ca. 8 nm that agglomerate forming bigger aggregates of 50 ± 1 nm.

Aqueous solutionMaterials sciencenanostructurePolymers and PlasticsElectron microscopy; nanostructures; oxides; surface propertiesSmall-angle X-ray scatteringNanoparticleMineralogyNanocrystalline materialSurfaces Coatings and FilmsDynamic light scatteringChemical engineeringTransmission electron microscopynanostructuresoxidesElectron microscopyHydrothermal synthesissurface propertiesCubic zirconiaoxidePhysical and Theoretical ChemistryJournal of Dispersion Science and Technology
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Effect of temperature on the growth of alfa-PbO2 nanostructures

2010

Abstract Ordered arrays of α-PbO 2 nanostructures were grown by galvanostatic anodic deposition into the channels of alumina templates. Electrodepositions were performed in an aqueous solution containing lead acetate and sodium acetate at pH 5.4. Bath temperature and electrodeposition time were varied to check their effect on the growth of nanostructures. It has been found that filling of alumina pores is independent of the time and electrodeposition temperature, whilst height and growth kinetics of nanostructures vary with both parameters. Temperature greatly influences morphology: wires grown at room temperature consisted of clusters of particles, leading to poorly compact structures, whi…

Aqueous solutionNanostructureMaterials scienceLead dioxide Nanostructures Template electrosynthesis Alumina membranes Metal oxideGeneral Chemical EngineeringNanowireLead dioxideNanotechnologyCrystal structureGrain sizechemistry.chemical_compoundSettore ING-IND/23 - Chimica Fisica ApplicatachemistryChemical engineeringElectrochemistryCrystalliteDeposition (law)
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