Interaction induced spatial correlations in a Disordered Glass

TL;DR

This paper reports a new charge-distribution feature in low-carrier-concentration In_{x}O electron glasses, revealing complex disorder-interaction effects and charge correlations not previously observed in Anderson insulators.

Contribution

It introduces a novel broad peak in field-effect measurements linked to charge correlations in low-N Anderson insulators, expanding understanding of electron-glass phenomena.

Findings

Feature is tunable by gate voltage.

Suppressed by temperature, field, or infrared light.

Reappears after relaxation period.

Abstract

A consequence of the disorder and Coulomb interaction competition is the electron-glass phase observed in several Anderson-insulators. The disorder in these systems, typically degenerate semiconductors, is stronger than the interaction, more so the higher is the carrier-concentration N of the system. Here we report on a new feature observed in the electron-glass phase of In_{x}O with the lowest N yet studied. The feature, resolved as a broad peak in field-effect measurements, has not been recognized in previously studied Anderson-insulators. Several empirical facts associated with the phenomenon are consistent with the conjecture that it reflects a correlated charge-distribution. In particular, the feature may be turned on and off by gate-voltage maneuvering, suggesting the relevance of charge-arrangements. It may also be suppressed by either; temperature, non-ohmic field, or exposure to infrared illumination. After being washed-out, the feature reappears when the system is allowed to relax for sufficiently long time. A puzzling aspect that arises is the apparent absence of the phenomenon when the carrier-concentration increases above a certain value. This is reminiscent of the glass-transition conundrum except that the role of temperature in the latter is played by disorder. Analysis of these findings highlights several issues that challenge our understanding of the disorder-interaction interplay in Anderson insulators.