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用于电化学应用的具有Ruddlesden-Popper结构的材料ALnInO:离子(氧离子、质子)电导率、吸水率与结构变化之间的关系

Materials ALnInO with Ruddlesden-Popper Structure for Electrochemical Applications: Relationship between Ion (Oxygen-Ion, Proton) Conductivity, Water Uptake, and Structural Changes.

作者信息

Tarasova Nataliia, Animitsa Irina

机构信息

The Institute of High Temperature Electrochemistry of the Ural Branch of the Russian Academy of Sciences, 620066 Ekaterinburg, Russia.

Institute of Natural Sciences and Mathematics, Ural Federal University, 620066 Ekaterinburg, Russia.

出版信息

Materials (Basel). 2021 Dec 24;15(1):114. doi: 10.3390/ma15010114.

DOI:10.3390/ma15010114
PMID:35009259
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8745910/
Abstract

In this paper, the review of the new class of ionic conductors was made. For the last several years, the layered perovskites with Ruddlesden-Popper structure ALnInO attracted attention from the point of view of possibility of the realization of ionic transport. The materials based on Ba(Sr)La(Nd)InO and the various doped compositions were investigated as oxygen-ion and proton conductors. It was found that doped and undoped layered perovskites BaNdInO, SrLaInO, and BaLaInO demonstrate mixed hole-ionic nature of conductivity in dry air. Acceptor and donor doping leads to a significant increase (up to ~1.5-2 orders of magnitude) of conductivity. One of the most conductive compositions BaNdCaInO demonstrates the conductivity value of 5 × 10 S/cm at 500 °C under dry air. The proton conductivity is realized under humid air at low (<500 °C) temperatures. The highest values of proton conductivity are attributed to the compositions BaNdCaInO and BaLa0InO (7.6 × 10 and 3.2 × 10 S/cm correspondingly at the 350 °C under wet air). The proton concentration is not correlated with the concentration of oxygen defects in the structure and it increases with an increase in the unit cell volume. The highest proton conductivity (with 95-98% of proton transport below 400 °C) for the materials based on BaLaInO was demonstrated by the compositions with dopant content no more that 0.1 mol. The layered perovskites ALnInO are novel and prospective class of functional materials which can be used in the different electrochemical devices in the near future.

摘要

本文对新型离子导体进行了综述。在过去几年中,具有Ruddlesden-Popper结构的层状钙钛矿ALnInO从实现离子传输可能性的角度引起了关注。对基于Ba(Sr)La(Nd)InO及其各种掺杂成分的材料作为氧离子和质子导体进行了研究。发现掺杂和未掺杂的层状钙钛矿BaNdInO、SrLaInO和BaLaInO在干燥空气中表现出混合的空穴-离子导电性质。受主和施主掺杂导致电导率显著增加(高达约1.5 - 2个数量级)。导电性最强的成分之一BaNdCaInO在干燥空气中500℃时的电导率值为5×10 S/cm。质子传导在低(<500℃)温度的潮湿空气中实现。质子电导率的最高值归因于成分BaNdCaInO和BaLa0InO(在潮湿空气中350℃时分别为7.6×10和3.2×10 S/cm)。质子浓度与结构中氧缺陷的浓度无关,并且随着晶胞体积的增加而增加。对于基于BaLaInO的材料,掺杂剂含量不超过0.1 mol的成分表现出最高的质子电导率(在400℃以下质子传输占95 - 98%)。层状钙钛矿ALnInO是一类新型且有前景的功能材料,在不久的将来可用于不同的电化学装置。

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