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Main Authors: Xiao, Chuanlian, Maier, Joachim
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.28029
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author Xiao, Chuanlian
Maier, Joachim
author_facet Xiao, Chuanlian
Maier, Joachim
contents We report on a new type of rectifier which is in full contact equilibrium and thus, if down-sized to the nanoscale, shows no drift even if exposed to elevated temperatures and/or extreme waiting times. This is in contrast to existing diodes which rely on frozen doping profiles and are hence non-equilibrium devices. Our rectifiers are related to Schottky diodes but employ "dopants" whose mobilities are high enough to follow the electrical field quickly but low enough to not compete with the electrons in terms of conductivities. In order to realize such a device based on mixed conductors, we use nanosized TiO2 films on Ru as a substrate which can store Li at the interface according to a job-sharing mechanism (Li-ions on the TiO2 side, electrons on the Ru side). The excellent functionality of this nanoionic device is demonstrated (e.g., current on-off ratio can exceed 6-7 orders of magnitude) and the additional advantages stressed (such as ease of preparation and tuning the characteristics electrochemically).
format Preprint
id arxiv_https___arxiv_org_abs_2604_28029
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A nanoionic diode: Equilibrium rectifying junction enabling large and stable resistance variations
Xiao, Chuanlian
Maier, Joachim
Other Condensed Matter
Mesoscale and Nanoscale Physics
Materials Science
We report on a new type of rectifier which is in full contact equilibrium and thus, if down-sized to the nanoscale, shows no drift even if exposed to elevated temperatures and/or extreme waiting times. This is in contrast to existing diodes which rely on frozen doping profiles and are hence non-equilibrium devices. Our rectifiers are related to Schottky diodes but employ "dopants" whose mobilities are high enough to follow the electrical field quickly but low enough to not compete with the electrons in terms of conductivities. In order to realize such a device based on mixed conductors, we use nanosized TiO2 films on Ru as a substrate which can store Li at the interface according to a job-sharing mechanism (Li-ions on the TiO2 side, electrons on the Ru side). The excellent functionality of this nanoionic device is demonstrated (e.g., current on-off ratio can exceed 6-7 orders of magnitude) and the additional advantages stressed (such as ease of preparation and tuning the characteristics electrochemically).
title A nanoionic diode: Equilibrium rectifying junction enabling large and stable resistance variations
topic Other Condensed Matter
Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2604.28029