Add to ORKGElectron-electron interaction is fundamental in condensed matter physics and can lead to composite quasiparticles called plasmarons, which strongly renormalize the dispersion and carry information of electron-electron coupling strength as defined by the effective fine structure constant αee*. Although h-BN with unique dielectric properties has been widely used as an important substrate for graphene, so far there is no experimental report of plasmarons in graphene/h-BN yet. Here, we report direct experimental observation of plasmaron dispersion in graphene/h-BN heterostructures through angle-resolved photoemission spectroscopy (ARPES) measurements upon in situ electron doping. Characteristic diamond-shaped dispersion is observed near the Dir...
International audienceStacking various two-dimensional atomic crystals is a feasible approach to cre...
This dissertation focuses on the study of the electronic properties of graphene using scanning tunne...
The many-body correction to the band structure of a quasi-free-standing graphene layer is obtained w...
Electron-electron interaction is fundamental in condensed matter physics and can lead to composite q...
A hallmark of graphene is its unusual conical band structure that leads to a zero-energy band gap at...
Electron-plasmon coupling in graphene has been shown recently to give rise to a “plasmaron” quasipar...
A hallmark of graphene is its unusual conical band structure that leads to a zero-energy band gap at...
In van der Waals heterostructures, the periodic potential from the Moiré superlattice can be used as...
Single-layer graphene has been widely researched in recent years due to its perceived technological ...
The relation between the energy and momentum of plasmarons in bilayer graphene is investigated withi...
The interaction between electrons and plasmons in trilayer graphene is investigated within the Overh...
International audienceA promising route towards nanodevice applications relies on the association of...
First-principles studies of the electron-phonon coupling in graphene predict a high coupling strengt...
Electronic systems are an indivisible part of modern life. Every day, new materials, devices, passiv...
International audienceStacking various two-dimensional atomic crystals is a feasible approach to cre...
This dissertation focuses on the study of the electronic properties of graphene using scanning tunne...
The many-body correction to the band structure of a quasi-free-standing graphene layer is obtained w...
Electron-electron interaction is fundamental in condensed matter physics and can lead to composite q...
A hallmark of graphene is its unusual conical band structure that leads to a zero-energy band gap at...
Electron-plasmon coupling in graphene has been shown recently to give rise to a “plasmaron” quasipar...
A hallmark of graphene is its unusual conical band structure that leads to a zero-energy band gap at...
In van der Waals heterostructures, the periodic potential from the Moiré superlattice can be used as...
Single-layer graphene has been widely researched in recent years due to its perceived technological ...
The relation between the energy and momentum of plasmarons in bilayer graphene is investigated withi...
The interaction between electrons and plasmons in trilayer graphene is investigated within the Overh...
International audienceA promising route towards nanodevice applications relies on the association of...
First-principles studies of the electron-phonon coupling in graphene predict a high coupling strengt...
Electronic systems are an indivisible part of modern life. Every day, new materials, devices, passiv...
International audienceStacking various two-dimensional atomic crystals is a feasible approach to cre...
This dissertation focuses on the study of the electronic properties of graphene using scanning tunne...
The many-body correction to the band structure of a quasi-free-standing graphene layer is obtained w...