From zero resistance states to absolute negative conductivity in microwave irradiated 2D electron systems

TL;DR

This paper presents a theoretical model explaining how microwave radiation induces a transition from zero resistance states to absolute negative conductivity in 2D electron gases, highlighting control via microwave parameters.

Contribution

The study introduces a model linking multiphoton-assisted scattering to negative conductivity, advancing understanding of microwave effects in 2D electron systems.

Findings

Negative conductivity can be induced by microwave radiation.

Transition from zero resistance to negative conductivity is controllable.

Implications for nanodevice electron dynamics.

Abstract

Recent experimental results regarding a 2D electron gas subjected to microwave radiation reveal that magnetoresistivity, apart from presenting oscillations and zero resistance states, can evolve to negative values at minima. In other words, the current can evolve from flowing with no dissipation, to flow in the opposite direction of the dc bias applied. Here we present a theoretical model in which the existence of radiation-induced absolute negative conductivity is analyzed. Our model explains the transition from zero resistance states to absolute negative conductivity in terms of multiphoton assisted electron scattering due to charged impurities. It shows as well, how this transition can be driven by tuning microwave frequency and intensity. Then it opens the possibility of controlling the electron Larmor orbits dynamics (magnetoconductivity) in microwave driven nanodevices. The analysis of zero resistance states is therefore promising because new optical and transport properties in nanodevices will be expected.