about
Giant modulation of the electronic band gap of carbon nanotubes by dielectric screening.Carbon nanotubes as excitonic insulators.Correlation effects in wave function mapping of molecular beam epitaxy grown quantum dots.Interaction-Driven Giant Orbital Magnetic Moments in Carbon NanotubesAngle-resolved photoemission spectroscopy from first-principles quantum Monte CarloObservation and spectroscopy of a two-electron Wigner molecule in an ultraclean carbon nanotubeEnhancement of Coulomb interactions in semiconductor nanostructures by dielectric confinementCoulomb correlation effects in semiconductor quantum dots: The role of dimensionalityMultiple quantum phases in artificial double-dot moleculesAddition energies in semiconductor quantum dots: Role of electron–electron interactionResponse to “Comment on ‘Field-controlled suppression of phonon-induced transitions in coupled quantum dots’ [Appl. Phys. Lett. 88, 4729 (2006)]”Interacting electrons in artificial molecules with magnetic field of arbitrary directionSuppression of acoustic-phonon-induced electron transitions in coupled quantum dotsCompeting mechanisms for singlet-triplet transition in artificial moleculesField-controlled suppression of phonon-induced transitions in coupled quantum dotsSpin–spin interaction in artificial molecules with in-plane magnetic fieldNanoscale spin rectifiers controlled by the Stark effectEvidence of Correlation in Spin Excitations of Few-Electron Quantum DotsReduced Electron Relaxation Rate in Multielectron Quantum DotsCorrelation Effects in Scanning Tunneling Microscopy Images of Molecules Revealed by Quantum Monte CarloProposed Alteration of Images of Molecular Orbitals Obtained Using a Scanning Tunneling Microscope as a Probe of Electron CorrelationVisualizing electron correlation by means of ab initio scanning tunneling spectroscopy images of single moleculesFew-Electron Molecular States and Their Transitions in a Single InAs Quantum Dot MoleculeFriedel sum rule for an interacting multiorbital quantum dotCold fermionic atoms in two-dimensional traps: pairing versus Hund's ruleArtificial atoms: Shape the waveTunneling theory of two interacting atoms in a trapCorrelated electrons in optically tunable quantum dots: building an electron dimer moleculeA monolayer transition-metal dichalcogenide as a topological excitonic insulator
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description
researcher ORCID ID = 0000-0001-5417-3159
@en
wetenschapper
@nl
name
Massimo Rontani
@ast
Massimo Rontani
@en
Massimo Rontani
@es
Massimo Rontani
@nl
type
label
Massimo Rontani
@ast
Massimo Rontani
@en
Massimo Rontani
@es
Massimo Rontani
@nl
prefLabel
Massimo Rontani
@ast
Massimo Rontani
@en
Massimo Rontani
@es
Massimo Rontani
@nl
P1153
6602692318
P21
P31
P496
0000-0001-5417-3159