Add to ORKGWe investigate theoretically the spectrum of a graphenelike sample (honeycomb lattice) subjected to a perpendicular magnetic field and irradiated by circularly polarized light. This system is studied using the Floquet formalism, and the resulting Hofstadter spectrum is analyzed for different regimes of the driving frequency. For lower frequencies, resonances of various copies of the spectrum lead to intricate formations of topological gaps. In the Landau-level regime, new winglike gaps emerge upon reducing the driving frequency, thus revealing the possibility of dynamically tuning the formation of the Hofstadter butterfly. In this regime, an effective model may be analytically derived, which allows us to retrace the energy levels that exhib...
The magnetic field generated Hofstadter butterfly in twisted trilayer graphene (TTLG) is investigate...
Abstract The presence of periodic modulation in graphene leads to a reconstruction of the band struc...
Electrons moving through a spatially periodic lattice potential develop a quantized energy spectrum ...
We investigate theoretically the spectrum of a graphenelike sample (honeycomb lattice) subjected to ...
The properties of the Hofstadter butterfly, a fractal, self-similar spectrum of a two-dimensional el...
In this work, we use Floquet theory to theoretically study the influence of monochromatic circularly...
Recent advances in realizing artificial gauge fields on optical lattices promise experimental detect...
Electromagnetic driving in a honeycomb lattice can induce gaps and topological edge states with a st...
We study the Hofstadter butterfly and Landau levels of the twisted bilayer graphene (TBG). We show t...
This is a short review of the recent progresses on Hofstadter butterfly in graphene, organized in th...
When submitted both to a magnetic field and a periodic potential, the energy spectrum of electrons e...
We present the results of numerical calculations of the energy levels and eigenfunctions of finite s...
<p><strong>Figure 2.</strong> Hofstadter butterfly: energy spectrum (black) as a function of magneti...
Self-similarity and fractals have fascinated researchers across various disciplines. In graphene pla...
We rely on a recent method for determining edge spectra and we use it to compute the Chern numbers f...
The magnetic field generated Hofstadter butterfly in twisted trilayer graphene (TTLG) is investigate...
Abstract The presence of periodic modulation in graphene leads to a reconstruction of the band struc...
Electrons moving through a spatially periodic lattice potential develop a quantized energy spectrum ...
We investigate theoretically the spectrum of a graphenelike sample (honeycomb lattice) subjected to ...
The properties of the Hofstadter butterfly, a fractal, self-similar spectrum of a two-dimensional el...
In this work, we use Floquet theory to theoretically study the influence of monochromatic circularly...
Recent advances in realizing artificial gauge fields on optical lattices promise experimental detect...
Electromagnetic driving in a honeycomb lattice can induce gaps and topological edge states with a st...
We study the Hofstadter butterfly and Landau levels of the twisted bilayer graphene (TBG). We show t...
This is a short review of the recent progresses on Hofstadter butterfly in graphene, organized in th...
When submitted both to a magnetic field and a periodic potential, the energy spectrum of electrons e...
We present the results of numerical calculations of the energy levels and eigenfunctions of finite s...
<p><strong>Figure 2.</strong> Hofstadter butterfly: energy spectrum (black) as a function of magneti...
Self-similarity and fractals have fascinated researchers across various disciplines. In graphene pla...
We rely on a recent method for determining edge spectra and we use it to compute the Chern numbers f...
The magnetic field generated Hofstadter butterfly in twisted trilayer graphene (TTLG) is investigate...
Abstract The presence of periodic modulation in graphene leads to a reconstruction of the band struc...
Electrons moving through a spatially periodic lattice potential develop a quantized energy spectrum ...