Enregistré dans:
Détails bibliographiques
Auteurs principaux: Argyrou, Aikaterini, Giappa, Rafaela Maria, Gagaoudakis, Emmanouil, Binas, Vasilios, Remediakis, Ioannis, Brintakis, Konstantinos, Kostopoulou, Athanasia, Stratakis, Emmanuel
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2406.13610
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866917292216942592
author Argyrou, Aikaterini
Giappa, Rafaela Maria
Gagaoudakis, Emmanouil
Binas, Vasilios
Remediakis, Ioannis
Brintakis, Konstantinos
Kostopoulou, Athanasia
Stratakis, Emmanuel
author_facet Argyrou, Aikaterini
Giappa, Rafaela Maria
Gagaoudakis, Emmanouil
Binas, Vasilios
Remediakis, Ioannis
Brintakis, Konstantinos
Kostopoulou, Athanasia
Stratakis, Emmanuel
contents Metal halide perovskites (MHPs) have attracted significant attention owing to their simple manufacturing process and unique optoelectronic properties. Their reversible electrical or optical properties changes in response to oxidizing or reducing environments make them prospective materials for gas detection technologies. Despite advancements in perovskite-based sensor research, the mechanisms behind perovskite-gas interactions, vital for sensor performance, are still unexclusive. This work presents the first evaluation of the sensing performance and long-term stability of MHPs, considering factors such as halide composition variation and Mn doping levels. The research reveals a clear correlation between halide composition and sensing behavior, with Br-rich sensors displaying a p-type response to O3 gas, while Cl-based counterparts exhibit an n-type sensing behavior. Notably, Mn-doping significantly enhances the O3 sensing performance by facilitating the gas adsorption process, as supported by both atomistic simulations and experimental evidence. Long-term evaluation of the sensors provides valuable insights into evolving sensing behaviors, highlighting the impact of dynamic instabilities over time. Overall, this research offers insights into optimal halide combination and Mn-doping levels, representing a significant step forward in engineering room temperature perovskite-based gas sensors that are not only low-cost and high-performing but also durable, marking a new era in sensor technology.
format Preprint
id arxiv_https___arxiv_org_abs_2406_13610
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Towards the optimization of a perovskite-based room temperature ozone sensor: A multifaceted approach in pursuit of sensitivity, stability, and understanding of mechanism
Argyrou, Aikaterini
Giappa, Rafaela Maria
Gagaoudakis, Emmanouil
Binas, Vasilios
Remediakis, Ioannis
Brintakis, Konstantinos
Kostopoulou, Athanasia
Stratakis, Emmanuel
Chemical Physics
Mesoscale and Nanoscale Physics
Materials Science
Metal halide perovskites (MHPs) have attracted significant attention owing to their simple manufacturing process and unique optoelectronic properties. Their reversible electrical or optical properties changes in response to oxidizing or reducing environments make them prospective materials for gas detection technologies. Despite advancements in perovskite-based sensor research, the mechanisms behind perovskite-gas interactions, vital for sensor performance, are still unexclusive. This work presents the first evaluation of the sensing performance and long-term stability of MHPs, considering factors such as halide composition variation and Mn doping levels. The research reveals a clear correlation between halide composition and sensing behavior, with Br-rich sensors displaying a p-type response to O3 gas, while Cl-based counterparts exhibit an n-type sensing behavior. Notably, Mn-doping significantly enhances the O3 sensing performance by facilitating the gas adsorption process, as supported by both atomistic simulations and experimental evidence. Long-term evaluation of the sensors provides valuable insights into evolving sensing behaviors, highlighting the impact of dynamic instabilities over time. Overall, this research offers insights into optimal halide combination and Mn-doping levels, representing a significant step forward in engineering room temperature perovskite-based gas sensors that are not only low-cost and high-performing but also durable, marking a new era in sensor technology.
title Towards the optimization of a perovskite-based room temperature ozone sensor: A multifaceted approach in pursuit of sensitivity, stability, and understanding of mechanism
topic Chemical Physics
Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2406.13610