In recent years, predictive computational modeling has become a cornerstone for the study
of fundamental electronic, optical, and thermal properties in complex forms of condensed …

Patterning antidots, which are regions of potential hills that repel electrons, into well-defined
antidot lattices creates fascinating artificial periodic structures, leading to anomalous …

We studied the thermal conductivity of graphene phononic crystal (GPnC), also named as
graphene nanomesh, by molecular dynamics simulations. The dependence of thermal …

Among the many anticipated applications of graphene, some–such as transistors for Si
microelectronics–would greatly benefit from the possibility to deposit graphene directly on a …

Tuning thermal conductivity of porous graphenes has attracted much interest in the thermal
management of nanoelectronics devices due to the promising multifunctional properties of …

Two-dimensional van der Waals materials such as graphene present an opportunity for
band structure engineering using custom superlattice potentials. In this study, we …

We study graphene antidot lattices (GALs) in magnetic fields. Using a tight-binding model
and a recursive Green's function technique that we extend to deal with periodic structures …

Gradual localization of charge carriers was studied in a series of micro-size samples of
monolayer graphene fabricated on the common large scale film and irradiated by different …

Different interatomic spin interactions in graphene-regulated Mn atomic clusters are
investigated by low-temperature scanning tunneling microscopy and magnetic-field …

Growth of large-scale graphene is still accompanied by imperfections. By means of a four-tip
scanning tunneling and electron microscope (4-tip STM/SEM), the local structure of …