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SERS active silver nanoparticles synthesized by inkjet printing on mesoporous siliconBioconjugate functionalization of thermally carbonized porous silicon using a radical coupling reactionDirect patterning of silver particles on porous silicon by inkjet printing of a silver salt via in-situ reductionTemporal trends of elements in Turin (Italy) atmospheric particulate matter from 1976 to 2001.Discrimination between washed Arabica, natural Arabica and Robusta coffees by using near infrared spectroscopy, electronic nose and electronic tongue analysis.Role of ice structuring proteins on freezing-thawing cycles of pasta sauces.Sonochemical preparation of high surface area MgAl2O4 spinel.Immobilization of Oligonucleotides on Metal-Dielectric Nanostructures for miRNA Detection.Protein immobilization on nanoporous silicon functionalized by RF activated plasma polymerization of Acrylic Acid.SERS-active metal-dielectric nanostructures integrated in microfluidic devices for label-free quantitative detection of miRNA.Switching of fluorescence mediated by a peroxynitrite-glutathione redox reaction in a porous silicon nanoreactor.A Nanostructured Porous Silicon Near Insulator Becomes Either a p- or an n-Type Semiconductor upon Gas AdsorptionBoron passivation and its reactivation in mesoporous silicon: a “chemical” modelESR Study of Conduction Electrons in B-Doped Porous Silicon Generated by the Adsorption of Lewis BasesChemisorption of NO2at Boron Sites at the Surface of Nanostructured Mesoporous SiliconReversible Insulator-to-Metal Transition in p+-Type Mesoporous Silicon Induced by the Adsorption of AmmoniaQ60169232Nitrosylic complexes in Ag(I)–ZSM-5: a comparison with Cu(I)–ZSM-5Spectroscopic study in the UV-Vis, near and mid IR of cationic species formed by interaction of thiophene, dithiophene and terthiophene with the zeolite H-YThe vibrational spectroscopy of H2, N2, CO and NO adsorbed on the titanosilicate molecular sieve ETS-10Evidence of the Presence of Two Different Framework Ti(IV) Species in Ti−Silicalite-1 in Vacuo Conditions: an EXAFS and a Photoluminescence StudyXANES, EXAFS and FTIR characterization of copper-exchanged mordeniteEvolution of Fe3+from Framework to Extra-Framework Species in Fe-Silicate as a Function of the Template Burning TemperaturePropene oligomerization on H-mordenite: Hydrogen-bonding interaction, chain initiation, propagation and hydrogen transfer studied by temperature-programmed FTIR and UV–VIS spectroscopiesXAFS, IR, and UV−Vis Study of the CuIEnvironment in CuI-ZSM-5FTIR Investigation of the Formation of Neutral and Ionic Hydrogen-Bonded Complexes by Interaction of H-ZSM-5 and H-Mordenite with CH3CN and H2O: Comparison with the H-NAFION Superacidic SystemIR spectroscopy of neutral and ionic hydrogen-bonded complexes formed upon interaction of CH3OH, C2H5OH, (CH3)2O, (C2H5)2O and C4H8O with H-Y, H-ZSM-5 and H-mordenite: comparison with analogous adducts formed on the H-Nafion superacidic membraneIR studies of CO and NO adsorbed on well characterized oxide single microcrystalsInfrared studies of the interaction of carbon monoxide and dinitrogen with ferrisilicate MFI-type zeolitesStructure and Reactivity of Framework and Extraframework Iron in Fe-Silicalite as Investigated by Spectroscopic and Physicochemical MethodsFormation of CuI—N2adducts at 298 and 77 K in CuI-ZSM-5: an FTIR investigationFourier-Transform Infrared Study of CO Adsorbed at 77 K on H-Mordenite and Alkali-Metal-Exchanged MordenitesN2 Adsorption at 77 K on H-Mordenite and Alkali-Metal-Exchanged Mordenites: An IR StudyStretching frequencies of cation‐CO adducts in alkali‐metal exchanged zeolites: An elementary electrostatic approachXANES study of Ti and Fe substituted silicalites in presence and in absence of NH3 and comparison with UV-vis, IR and Raman spectraFourier-transform infrared and Raman spectra of pure and Al-, B-, Ti- and Fe-substituted silicalites: stretching-mode regionDRS UV-Vis and EPR spectroscopy of hydroperoxo and superoxo complexes in titanium silicaliteFree carriers reactivation on p+-mesoporous silicon through ammonia adsorption: a FTIR studyPorous silicon in NO2: A chemisorption mechanism for enhanced electrical conductivitySensing CO2 in a chemically modified porous silicon film
P50
Q34285047-1980CFB3-1D80-4130-90EF-49BAB86BAE70Q34636413-C13B3D23-8E80-42D3-8AE5-1610D608AB35Q36478353-2E6E22D4-60AA-437B-AEE1-1C8563154E8AQ40079741-79BED8E7-DC63-476B-A582-984510A0CECFQ43662054-5C04783B-9817-4F69-B04B-416308976979Q46134299-51BA41AC-A2BE-44C8-8F3D-64AA39B200FCQ46460459-E3435821-F77F-4574-B012-3A0BF2224531Q46492549-6A19517B-2B83-47EE-B03F-589344D2D4F8Q46517346-EC999E48-B95D-4A8A-BD3A-B9893DE21F34Q50201625-D00AA01E-E338-41CA-99AE-FC288431F07CQ51541522-F6DDC722-51B9-447D-8641-A2A97C2859F1Q59427177-6483558B-AD25-4F7A-9E0A-14B5BFDF7EF0Q59427179-77A1E9CF-2F7D-4617-AF98-170F5D444826Q59427181-B110D145-B856-4FEE-96AF-6EB59868C5F1Q59427191-F0DF78FA-612E-4055-BAA6-9BA49503F2DFQ59427204-A358BC5C-B390-4439-9B5B-A99804362138Q60169232-7DA18204-A9FA-416D-B3EF-962C1A2638ADQ60169236-0F1392DA-6584-4362-9134-067E7DAC1D55Q60169237-B2F107E9-E292-4F9F-A935-56E98268C141Q60169240-C379C76E-5E5B-4D0E-A6A8-E46438D023A7Q60169242-B2DE5FC0-CFD6-4499-8E71-FE4BDA42BFF7Q60169251-BAF39286-2BCD-4BA0-8694-F5B66B973D78Q60169258-5A6E721A-075E-43F8-82D7-50338ECF4E97Q60169259-C823EF0D-6978-4E6A-82FD-BEDE50FE150DQ60169269-C488158B-CE28-4658-B450-10C1E37F635AQ60169270-FD7CD576-6D49-4A40-954C-10A4D4B83C32Q60169271-0268DC6E-5FFE-4173-932F-1B670953D476Q60169272-54ECB0D1-3922-432C-8F77-A32DD9F6768EQ60169273-901E2222-A718-4F76-8B08-BB4FB01E42BEQ60169280-A6EAFA81-FF9F-4E41-8CC1-8C6908E6171BQ60169283-DDEA7475-9878-44AF-8238-BD9AEE404B57Q60169284-2AE0B953-5B59-46C4-A09F-A065C69E1CBAQ60169286-D75E53E6-6E29-4402-BF8E-AABF6C86BA8CQ60169287-53F03CDF-2FFD-4CC9-915C-C49AF9F82FDBQ60169289-BAAE176C-1DD7-4565-B449-14063E5CD0A4Q60169305-9DF2A248-4B01-4F62-8821-25F7CC37DC29Q60169319-A3AC1758-B015-4C55-91B9-89FFE34B6D14Q60243754-500CB5DD-457B-4560-9E3E-AE1986B343B3Q60243760-9BE07266-75B8-497A-B350-DA003FA798CFQ60243762-60017B7B-994D-4FE2-9329-3B05D3116020
P50
description
researcher ORCID ID = 0000-0002-9855-4874
@en
wetenschapper
@nl
name
Francesco Geobaldo
@ast
Francesco Geobaldo
@en
Francesco Geobaldo
@es
Francesco Geobaldo
@nl
type
label
Francesco Geobaldo
@ast
Francesco Geobaldo
@en
Francesco Geobaldo
@es
Francesco Geobaldo
@nl
prefLabel
Francesco Geobaldo
@ast
Francesco Geobaldo
@en
Francesco Geobaldo
@es
Francesco Geobaldo
@nl
P106
P1153
7004492012
P21
P31
P496
0000-0002-9855-4874