0000000000249673

AUTHOR

Giovanni Agostini

0000-0003-1508-3809

showing 7 related works from this author

Use of alkylarsonium directing agents for the synthesis and study of zeolites

2019

[EN] Expanding the previously known family of -onium (ammonium, phosphonium, and sulfonium) organic structure-directing agents (OSDAs) for the synthesis of zeolite MFI, a new member, the arsonium cation, is used for the first time. The new group of tetraalkylarsonium cations has allowed the synthesis of the zeolite ZSM-5 with several different chemical compositions, opening a route for the synthesis of zeolites with a new series of OSDA. Moreover, the use of As replacing N in the OSDA allows the introduction of probe atoms that facilitate the study of these molecules by powder X-ray diffraction (PXRD), solid-state nuclear magnetic resonance (MAS NMR), and X-ray absorption spectroscopy (XAS)…

X-ray absorption spectroscopyChemistrySulfoniumOrganic ChemistryGeneral ChemistryOniumAlkylarsoniumCatalysislaw.inventionArsenicchemistry.chemical_compoundCrystallographyCompostos orgànics SíntesiStructure-directing agentslawCationsQUIMICA ANALITICAZeolitesMoleculePhosphoniumCrystallizationZeoliteMaterialsPowder diffraction
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Effect of Pre-Reduction on the Properties and the Catalytic Activity of Pd/Carbon Catalysts: A Comparison with Pd/Al2O3

2013

The effect of pre-reduction in solution with chemical reagents on the catalytic performance and catalyst properties of Pd/carbon catalysts was systematically investigated with a multitechnique approach. The results are critically discussed in comparison to those recently obtained on analogous Pd/alumina catalysts. It was proved that the Pd phase on the carbon surface is characterized by a high mobility, opposite to what occurs on alumina. As a result, the Pd particles on carbon aggregate together during pre-reduction, with a consequent decrease in available metal surface. Pd particles remain aggregated also in reaction conditions; the decreased Pd dispersion negatively affects the catalyst …

characterization techniqueCO chemisorptionInorganic chemistryPd-based catalystchemistry.chemical_elementTPRHeterogeneous catalysisPd/CarbonCatalysisCatalysisMetalCharacterization techniquesCatalyst pre-reductionTemperature-programmed reductionX-ray absorption spectroscopymetal nanoparticlein situPd-based catalystsPd/aluminaSAXSGeneral ChemistryXANESSmall Angle X-ray ScatteringX-ray Absorption SpectroscopyPd/Carbon; Pd/alumina; metal nanoparticle; catalysis; Catalyst pre-reduction; in situ; SAXS; XANES; Pd-based catalysts; heterogeneous catalysis; Characterization techniques; Temperature-programmed reduction; TPR; CO chemisorption; TEM; X-ray absorption spectroscopy; Small Angle X-ray Scatteringheterogeneous catalysischemistryReagentvisual_arttemperature-programmed reductionvisual_art.visual_art_mediumTEMheterogeneous catalysiSmall Angle X-ray SpectroscopyDispersion (chemistry)Carbon
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Formation and growth of palladium nanoparticles inside porous poly(4-vinyl-pyridine) monitored by operando techniques: The role of different reducing…

2017

In this work we followed the formation of palladium nanoparticles, starting from palladium (II) acetate precursor, inside a poly(4-vinylpyridine-co-divinylbenzene) polymer in presence of different reducing agents. The formation and growth of palladium nanoparticles in presence of H-2 was followed as a function of temperature by simultaneous XANES-SAXS techniques, coupled with DRIFT spectroscopy in operando conditions. It was found that the pyridyl functional groups in the polymer plays a fundamental role in the stabilization of the palladium (II) acetate precursor, as well as in the stabilization of the palladium nanoparticles. The effect of a thermal treatment in alcohol (ethanol and 2-pro…

inorganic chemicalsReducing agentInfrared spectroscopychemistry.chemical_element02 engineering and technologyThermal treatment010402 general chemistryPhotochemistry01 natural sciencesAEROBIC ALCOHOL OXIDATIONCatalysisCatalysiCatalysisP4VPRUTHENIUM NANOPARTICLESMoleculeOrganic chemistryOperandoCATALYTIC-ACTIVITYchemistry.chemical_classificationPD NANOPARTICLESDRIFT; Operando; P4VP; Palladium nanoparticles; SAXS; XANESChemistryIN-SITUChemistry (all)SAXSGeneral ChemistryPolymerPalladium nanoparticleSELECTIVE OXIDATION021001 nanoscience & nanotechnologyPalladium nanoparticlesXANESX-RAY-SCATTERINGPARTICLE-SIZE0104 chemical sciencesDRIFTColloidal goldGOLD NANOPARTICLESVIBRATIONAL PROPERTIESDRIFT; Operando; P4VP; Palladium nanoparticles; SAXS; XANES; Catalysis; Chemistry (all)0210 nano-technologyPalladiumCatalysis Today
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The Pyridyl Functional Groups Guide the Formation of Pd Nanoparticles Inside A Porous Poly(4-Vinyl-Pyridine)

2015

The reactivity of palladium acetate inside a poly(4-vinylpyridine-co-divinylbenzene) polymer is strongly influenced by the establishment of interaction between the Pd precursor and the pyridyl functional group in the polymer. Diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) and simultaneous X-ray absorption near edge structure (XANES) and small angle X-ray scattering (SAXS) techniques have been applied to monitor the reactivity of palladium acetate in the presence of H-2 and CO as a function of temperature. H-2 reduces palladium acetate to Pd nanoparticles and acetic acid. The pyridyl groups in the polymer play a vital role both in stabilizing the formed acetic acid, thu…

INFRARED-SPECTRADiffuse reflectance infrared fourier transformpolymersmall angle X-ray scatteringInfrared spectroscopychemistry.chemical_elementPALLADIUM(II) ACETATEIR spectroscopy; nanoparticles; palladium; polymers; small angle X-ray scattering; X-ray absorption spectroscopyPhotochemistryCatalysisCatalysisInorganic ChemistryAcetic acidchemistry.chemical_compoundRUTHENIUM NANOPARTICLESPARTICLE FORMATIONENVIRONMENTALLY BENIGNReactivity (chemistry)Physical and Theoretical ChemistryCARBON-MONOXIDEpolymerschemistry.chemical_classificationPOLYMERIC SUPPORTSnanoparticleIN-SITUOrganic ChemistryIR spectroscopy; nanoparticles; palladium; polymers; small angle X-ray scattering; X-ray absorption spectroscopy; Inorganic Chemistry; Organic Chemistry; Physical and Theoretical Chemistry; CatalysisX-ray absorption spectroscopyPolymerpalladiumchemistryIR spectroscopynanoparticlesPalladium(II) acetateTRANSITION-METAL COORDINATIONRESOLVED SAXS ANALYSISPalladium
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Formation and Growth of Pd Nanoparticles Inside a Highly Cross-Linked Polystyrene Support: Role of the Reducing Agent

2014

Simultaneous time-resolved SAXS and XANES techniques were employed to follow in situ the formation of Pd nanoparticles in a porous polystyrene support, using palladium acetate as a precursor and gaseous H2 or CO as reducing agents. These results, in conjunction with data obtained by diffuse reflectance UV–vis and DRIFT spectroscopy and TEM measurements, allowed unraveling of the different roles played by gaseous H2 and CO in the formation of the Pd nanoparticles. In particular, it was found that the reducing agent affects (i) the reduction rate (which is faster in the presence of CO) and (ii) the properties of the hosted nanoparticles, in terms of size (bigger with CO), morphology (spherica…

Materials scienceExtended X-ray absorption fine structureReducing agentSmall-angle X-ray scatteringchemistry.chemical_elementNanoparticlePd nanoparticles; SAXS; EXAFSSAXSXANESSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsCrystallographychemistry.chemical_compoundEXAFSGeneral EnergyPd nanoparticleschemistryChemical engineeringPalladium nanoparticles time-resolved X-ray Absorption Spectroscopy Small Angle X-ray Spectroscopy Transmission Electron MicroscopyDiffuse reflectionPolystyrenePhysical and Theoretical ChemistryPalladium
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Pd nanoparticles formation inside porous polymeric scaffolds followed by in situ XANES/SAXS

2015

International audience; Simultaneous time-resolved SAXS and XANES techniques were employed to follow in situ the formation of Pd nanoparticles from palladium acetate precursor in two porous polymeric supports: polystyrene (PS) and poly(4-vinyl-pyridine) (P4VP). In this study we have investigated the effect of the use of different reducing agents (H-2 and CO) from the gas phase. These results, in conjunction with data obtained by diffuse reflectance IR (DRIFT) spectroscopy and TEM measurements, allowed us to unravel the different roles played by gaseous H-2 and CO in the formation of the Pd nanoparticles for both PS and P4VP hosting scaffolds

HistoryMaterials scienceAbsorption spectroscopyNanoparticlechemistry.chemical_elementreduction02 engineering and technologypolystyrene010402 general chemistry01 natural sciencesEducationP4VPchemistry.chemical_compoundPdPd nanoparticles formation inside porous polymeric scaffoldspaladumchemistry.chemical_classification[PHYS]Physics [physics]Small-angle X-ray scatteringnanoparticlein situSAXS XANES Pd paladum nanoparticle polystyrene P4VP DRIFT TEM reduction in situSAXSPolymer021001 nanoscience & nanotechnologyXANESXANES0104 chemical sciencesComputer Science ApplicationsCrystallographyDRIFTchemistryChemical engineeringTEMPolystyreneDiffuse reflection0210 nano-technologyPalladium
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CCDC 1910863: Experimental Crystal Structure Determination

2019

Related Article: Sara Sáez-Ferre, Christian W. Lopes, Jorge Simancas, Alejandro Vidal-Moya, Teresa Blasco, Giovanni Agostini, Guillermo Mínguez Espallargas, Jose L. Jordá, Fernando Rey, Pascual Oña-Burgos|2019|Chem.-Eur.J.|25|16390|doi:10.1002/chem.201904043

Space GroupCrystallographytetraethylarsanium iodide sesquihydrateCrystal SystemCrystal StructureCell ParametersExperimental 3D Coordinates
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