A quantum drift-diffusion model and its use into a hybrid strategy for strongly confined nanostructures
DOI10.3934/krm.2019010zbMath1477.35194OpenAlexW2886485459WikidataQ129428976 ScholiaQ129428976MaRDI QIDQ1728012
Paola Pietra, Clément Jourdana
Publication date: 21 February 2019
Published in: Kinetic and Related Models (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.3934/krm.2019010
Schrödinger equationhybrid couplingquantum drift-diffusion modelentropy minimizationcarbon nanotube FETsconfined nanostructures
PDEs in connection with optics and electromagnetic theory (35Q60) PDEs in connection with quantum mechanics (35Q40) Statistical mechanics of semiconductors (82D37) Applications to the sciences (65Z05) Motion of charged particles (78A35) Statistical mechanics of nanostructures and nanoparticles (82D80)
Cites Work
- Unnamed Item
- Analysis of a diffusive effective mass model for nanowires
- A problem of moment realizability in quantum statistical physics
- Quantum transport in crystals: Effective mass theorem and k\(\cdot\)p Hamiltonians
- A 1D coupled Schrödinger drift-diffusion model including collisions
- Diffusive limit of the two-band \(k\cdot p\) model for semiconductors
- Numerical study of quantum transport in carbon nanotube transistors
- A hybrid kinetic-quantum model for stationary electron transport
- On a one-dimensional Schrödinger-Poisson scattering model
- Quantum moment hydrodynamics and the entropy principle
- Moment closure hierarchies for kinetic theories.
- Quantum energy-transport and drift-diffusion models
- A coupled Schrödinger drift-diffusion model for quantum semiconductor device simulations
- Finite element approximation of electrostatic potential in one dimensional multilayer structures with quantized electronic charge
- A Positivity-Preserving Numerical Scheme for a Nonlinear Fourth Order Parabolic System
- A Hybrid Classical-Quantum Transport Model for the Simulation of Carbon Nanotube Transistors
- Subband Diffusion Models for Quantum Transport in a Strong Force Regime
- Thermodynamic derivation of the hydrodynamical model for charge transport in semiconductors
- AN EFFECTIVE MASS MODEL FOR THE SIMULATION OF ULTRA-SCALED CONFINED DEVICES
- Quantum drift-diffusion modeling of spin transport in nanostructures
- Semiconductor Simulations Using a Coupled Quantum Drift‐Diffusion Schrödinger–Poisson Model
- An inverse problem in quantum statistical physics
This page was built for publication: A quantum drift-diffusion model and its use into a hybrid strategy for strongly confined nanostructures
