Litcius/Paper detail

Electro-thermal transport in disordered nanostructures: a modeling perspective

Fabian Ducry, Jan Aeschlimann, Mathieu Luisier

2020Nanoscale Advances15 citationsDOIOpen Access PDF

Abstract

Following the emergence of novel classes of atomic systems with amorphous active regions, device simulations had to rapidly evolve to devise strategies to account for the influence of disordered phases, defects, and interfaces into its core physical models. We review here how molecular dynamics and quantum transport can be combined to shed light on the performance of, for example, conductive bridging random access memories (CBRAM), a type of non-volatile memory. In particular, we show that electro-thermal effects play a critical role in such devices and therefore present a method based on density functional theory and the non-equilibrium Green's function formalism to accurately describe them. Three CBRAM configurations are investigated to illustrate the functionality of the proposed modeling approach.

Topics & Concepts

Bridging (networking)Formalism (music)Amorphous solidNanostructureNanotechnologyThermalPerspective (graphical)Molecular dynamicsMaterials scienceElectrical conductorComputer scienceQuantumStatistical physicsPhysicsChemistryQuantum mechanicsMeteorologyOrganic chemistryArtComputer networkVisual artsComposite materialArtificial intelligenceMusicalAdvanced Memory and Neural ComputingSemiconductor materials and devicesPhase-change materials and chalcogenides