Full-wave multiphysics techniques aimed at the investigation of the combined electromagnetic-coherent transport phenomena in carbonbased nano-structures/devices are presented. Advanced numerical tools, in the frequency (energy)-domain and timedomain and in multi-scale environment are derived. The quantum transport is modeled by i) discrete Hamiltonians at atomistic scale, ii) Schrödinger equation, and/or Dirac/Dirac-like eqs. at continuous level. In the frequency-domain, a rigorous Poisson-coherent transport equation system is provided
Full-wave techniques for the multi-physics modeling and design of nano-structured devices / Pierantoni, Luca; Mencarelli, Davide. - ELETTRONICO. - (2015), pp. 34-35. (Intervento presentato al convegno NATO Advanced Research Workshop on Fundamental and Applied NanoElectroMagnetics”, FANEM 2015 tenutosi a Belarus State University, Minsk, Belarus nel May 25 – 27, 2015).
Full-wave techniques for the multi-physics modeling and design of nano-structured devices
PIERANTONI, Luca;MENCARELLI, Davide
2015-01-01
Abstract
Full-wave multiphysics techniques aimed at the investigation of the combined electromagnetic-coherent transport phenomena in carbonbased nano-structures/devices are presented. Advanced numerical tools, in the frequency (energy)-domain and timedomain and in multi-scale environment are derived. The quantum transport is modeled by i) discrete Hamiltonians at atomistic scale, ii) Schrödinger equation, and/or Dirac/Dirac-like eqs. at continuous level. In the frequency-domain, a rigorous Poisson-coherent transport equation system is providedI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
