about
Long-Lived Hot Carriers in III-V Nanowires.Single photons on demand from novel site-controlled GaAsN/GaAsN:H quantum dots.Manganese-induced growth of GaAs nanowires.Bundling of GaAs nanowires: a case of adhesion-induced self-assembly of nanowires.Fabrication of Site-Controlled Quantum Dots by Spatially Selective Incorporation of Hydrogen in Ga(AsN)/GaAs HeterostructuresQuantum confinement effects in hydrogen-intercalatedGa1−xAsxNx-GaAs1−xNx:Hplanar heterostructures investigated by photoluminescence spectroscopyLight polarization control in strain-engineered GaAsN/GaAsN:H heterostructuresEffect of hydrogen incorporation temperature in in plane-engineered GaAsN∕GaAsN:H heterostructuresLattice-matched Zn1−yCdySe/InxGa1−xAs(0 0 1) heterostructuresStrain and surface morphology in lattice-matched ZnSe/InxGa1−xAs heterostructuresA Roadmap for Controlled and Efficient n-Type Doping of Self-Assisted GaAs Nanowires Grown by Molecular Beam EpitaxyFormation of axial metal–semiconductor junctions in GaAs nanowires by thermal annealingSingle photon emitters in dilute nitrides: Towards a determinist approach of quantum dot-photonic crystal nanocavity couplingImaging with low-voltage scanning transmission electron microscopy: a quantitative analysis.Native oxides formation and surface wettability of epitaxial III–V materials: The case of InP and GaAsEpitaxial Al/GaN and Au/GaN junctions on as-grown GaN(0001)1 × 1 surfacesStructural and electronic properties of wide band gap Zn1−xMgxSe alloysAn all optical mapping of the strain field in GaAsN/GaAsN:H wiresConvergent beam electron-diffraction investigation of lattice mismatch and static disorder in GaAs/GaAs1−xNx intercalated GaAs/GaAs1−xNx:H heterostructuresMicroscopic origin of compressive strain in hydrogen-irradiated dilute GaAs1−yNyalloys: Role of N-Hncenters withn>2and their thermal stabilityGiant and reversible enhancement of the electrical resistance of GaAs1−xNxby hydrogen irradiationOptical study of hydrogen-irradiated GaAsN/GaAs heterostructuresDetailed structure of the H-N-H center inGaAsyN1−yrevealed by vibrational spectroscopy under uniaxial stressHydrogen diffusion inGaAs1−xNxPhotoluminescence under magnetic field and hydrostatic pressure for probing the electronic properties of GaAsNIn-Plane Band Gap Engineering by Hydrogenation of Dilute Nitride SemiconductorsPhotoluminescence under magnetic field and hydrostatic pressure in GaAs1−xNx for probing the compositional dependence of carrier effective mass and gyromagnetic ratioPhotoreflectance and reflectance investigation of deuterium-irradiated GaAsNElectronic structure and the martensitic transformation in beta -phase Ni-Al alloys: 27Al NMR and specific-heat measurementsQuasiharmonic and molecular-dynamics study of the martensitic transformation in Ni-Al alloysNMR investigation of the martensitic transformation in fine particles of Ni-Al alloysMartensitic transformation in Ag-Cd and Cu-Zn alloys studied by nuclear magnetic resonanceErratum: Quasiharmonic and molecular-dynamics study of the martensitic transformation in Ni-Al alloysStructural and dynamical properties of metastable Al:Si solid solutions calculated by the embedded-atom methodPhonon localization and martensitic transformation in NixAl1-x alloysEmbedded-atom model of glass-forming Si-metal alloysMartensitic transformation in a Cu-Zn-Al alloy studied by 63Cu and 27Al NMRDetermination of exciton reduced mass and gyromagnetic factor of wurtzite (InGa)As nanowires by photoluminescence spectroscopy under high magnetic fieldsTuning the growth mode of nanowires via the interaction among seeds, substrates and beam fluxes
P50
Q35996917-828B80BE-BE76-4746-B098-1EDF8983A609Q39259036-35D60A3C-3ECC-49B7-9EF8-416EBFA188B5Q51134134-DDDAB523-7B4A-4BE4-A2A5-A8281EC1C0C9Q53463411-3D178119-0318-4D29-9896-8327E8B781BEQ58483864-F228585A-0A1C-4E2E-975D-D7DBF10287FCQ58483887-88F07641-7130-44F0-8003-EC0B077BAC25Q58483893-07372588-6C6D-41E2-96C6-E32284232158Q58483900-847AEDBE-FDF3-44C0-BAB8-AFC510974172Q59386116-05108316-1097-49C7-A530-C8AE37987032Q59386128-5D50D447-325F-40DE-AB13-1E3DAE29F2F5Q60161217-FF7BE636-D9AA-4902-ABDE-346C2C506AF7Q60161219-55D5A752-33E6-4627-BB82-C9244777D997Q61625821-F8DE6C2D-88D3-4207-8509-5423B54A1EEFQ61935504-60F15905-1016-470B-B123-B892BEF8DDEEQ62037553-B5184883-6270-464C-B14E-275754D84E45Q62037718-7AE6F5C6-0837-46F9-998F-05F8FE7CA746Q62037748-51AD32BB-BFE0-4801-8425-80EAE31197FCQ62048838-D0522D6F-3E8A-4D32-AAF7-7272F7BBC87DQ62048840-6ACA8629-F515-46D8-A28A-4CB1B1A50642Q62048846-C535404C-6E12-436D-9966-080C244109FFQ62048848-C93BFC73-64AC-456E-8595-477466E12040Q62048850-5D0C5A57-8557-40BD-8D98-AB1C3C9A8A6BQ62048853-88C4DE46-2AC2-4BD8-B19F-6408ED3F1717Q62048854-AC4E5EEB-4F1E-4D3C-97AC-A9A72CB0609CQ62048858-E42F8305-41BD-4470-945F-3C70934CFCADQ62048862-EE69CEEE-983A-4BD7-A3AC-55731F8F39BCQ62048864-12A802F0-BE64-43E5-B603-9B5EE01E27A8Q62048865-3E7DB80C-1E5B-4BA8-8181-D2F62F64CC13Q74365060-9392324D-8983-4329-B5DF-996D49D2BA57Q74384449-54D596B3-5872-4134-BD7C-A067AC22F8BAQ74399342-CF77507A-12E1-4AA9-A0E2-223EDBE068F7Q74401757-D84D045A-4407-4DC5-85EB-2FF447D6B398Q74404058-A8A42C30-96DC-486A-A3AF-0AC1BF878C59Q78113802-398545CF-C6CA-4A11-B2D3-FC2B7CA4A8BDQ78116772-D45E0D08-E275-4D2A-AFE7-E6B45E3E6492Q78127268-99527ABB-CA2E-459C-916D-F2860FEF6F1EQ78219772-4BB6B7AA-924F-4D5E-ABB1-3B16DA300B8BQ86820114-F1B1E835-1075-4ACC-A8B4-2A2022FF4C28Q88105084-F99C85F8-D3BC-43A1-8C6D-133C3B945B0B
P50
description
Forscher
@de
chercheur
@fr
hulumtuese
@sq
investigador
@es
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
研究者
@zh
name
Silvia Rubini
@ast
Silvia Rubini
@en
Silvia Rubini
@es
Silvia Rubini
@nl
type
label
Silvia Rubini
@ast
Silvia Rubini
@en
Silvia Rubini
@es
Silvia Rubini
@nl
prefLabel
Silvia Rubini
@ast
Silvia Rubini
@en
Silvia Rubini
@es
Silvia Rubini
@nl
P106
P1153
56187258600
P21
P31
P496
0000-0001-5215-2223