Quantum fluid (or hydrodynamic) models provide an attractive alternative for the modeling
and simulation of the electron dynamics in nano-scale objects. Compared to more standard …

In this paper we present a hydrodynamical model for the description of the charge transport
in graphene, including heating effects on the crystal lattice, and conversely the influence of …

A quantum hydrodynamic model for charge transport in graphene is derived from a moment
expansion of the Wigner–Boltzmann equation. The needed closure relations are obtained …

Charge transport in suspended monolayer graphene is simulated by a numerical
deterministic approach, based on a discontinuous Galerkin (DG) method, for solving the …

A hydrodynamical model for simulating charge transport in graphene is formulated by using
of the maximum entropy principle. Both electrons in the conduction band and holes in the …

In the last two decades, the Maximum Entropy Principle (MEP) has been successfully
employed to construct macroscopic models able to describe the charge and heat transport in …

Nissuna umana investigazione si pò dimandare vera scienzia s' essa non passa per le
matematiche dimostrazioni, e se tu dirai che le scienzie, che principiano e finiscono nella …

We present a macroscopic model for describing the electrical and thermal behaviour of
silicon devices. The model makes use of a set of macroscopic state variables for phonons …

Thermal effects in monolayer graphene under an electron flow are investigated with a Monte
Carlo (MC) analysis. The crystal heating is described by simulating the phonon dynamics. In …

Thermal effects in monolayer graphene due to an electron flow are investigated with a direct
simulation Monte Carlo (DSMC) analysis. The crystal heating is described by simulating the …