Enhancing efficiency and power of quantum-dots resonant tunneling thermoelectrics in three-terminal geometry by cooperative effects

TL;DR

This paper introduces a multilayer thermoelectric engine utilizing quantum dots in a three-terminal setup, where cooperative effects between elastic and inelastic transport processes significantly enhance efficiency and power output.

Contribution

It proposes a novel multilayer quantum-dot thermoelectric scheme leveraging cooperative effects between different transport processes to improve thermoelectric performance.

Findings

Enhanced figure of merit and power factor due to cooperative effects

Robust performance against phonon heat conduction and energy broadening

Numerical confirmation of efficiency improvements in realistic conditions

Abstract

We propose a scheme of multilayer thermoelectric engine where {\em one} electric current is coupled to {\em two} temperature gradients in three-terminal geometry. This is realized by resonant tunneling through quantum dots embedded in two thermal and electrical resisting polymer matrix layers between highly conducting semiconductor layers. There are two thermoelectric effects, one of which is pertaining to inelastic transport processes (if energies of quantum dots in the two layers are different) while the other exists also for elastic transport processes. {These two correspond to the transverse and longitudinal thermoelectric effects respectively and are associated with different temperature gradients.} We show that cooperation between the two thermoelectric effects leads to markedly improved figure of merit and power factor {which is confirmed by numerical calculation using material parameters. Such enhancement is robust against phonon heat conduction and energy level broadening. Therefore we demonstrated cooperative effect as an additional way to effectively improve performance of thermoelectrics in three-terminal geometry.