Wave function mapping conditions in Open Quantum Dots structures

TL;DR

This paper investigates the minimal conditions required for wave function spectroscopy in open quantum dots and resonant tunneling diodes, highlighting the importance of potential control and the system's tunability.

Contribution

It establishes the parameter conditions for effective wave function mapping via resonant tunneling and analyzes the impact of potential shape and extension on the mapping process.

Findings

Wave function mapping conditions depend on specific parameter regions.

Potential shape and extension are less critical for wave function mapping.

Open quantum dots can be tuned to realize Fano interference in the mapping regime.

Abstract

We discuss the minimal conditions for wave function spectroscopy, in which resonant tunneling is the measurement tool. Two systems are addressed: resonant tunneling diodes, as a toy model, and open quantum dots. The toy model is used to analyze the crucial tunning between the necessary resolution in current-voltage characteristics and the breakdown of the wave functions probing potentials into a level splitting characteristic of double quantum wells. The present results establish a parameter region where the wavefunction spectroscopy by resonant tunneling could be achieved. In the case of open quantum dots, a breakdown of the mapping condition is related to a change into a double quantum dot structure induced by the local probing potential. The analogy between the toy model and open quantum dots show that a precise control over shape and extention of the potential probes is irrelevant for wave function mapping. Moreover, the present system is a realization of a tunable Fano system in the wave function mapping regime.