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Grain Boundary Engineering to Improve Ionic Conduction in Thin Films for micro-SOFCs

机译：晶粒边界工程可改善微型SOFC薄膜中的离子传导性

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New emerging disciplines are specifically devoted to study trivial and non-trivial effects resulting from working in the nanoscale, however, the implementation of these nanostructures in real devices is still a major challenge. Thin film deposition and silicon microtechnology is probably the most promising and straightforward combination for the reliable integration of nanomaterials in real devices. In particular, the implementation of pure ionic and mixed ionic/electronic conductors (MIECs) in thin film form allows the miniaturization of multiple solid state devices such as solid oxide fuel cells (SOFCs). In this work, we will present the implementation of novel nanoionics concepts in micro-SOFCs by using micro and nanofabrication technologies. We will put special attention on the contribution of grain boundaries to the mass transport properties in interface-dominated materials such as thin films. Grain boundary engineering will be presented as a powerful tool for reducing the resistance associated to electrolytes and even control the intrinsic transport nature and performance of MIEC materials.

机译：新兴学科专门研究纳米工作产生的琐碎和非琐碎的影响，但是，在实际设备中实现这些纳米结构仍然是一个重大挑战。薄膜沉积和硅微技术可能是纳米材料在实际设备中可靠集成的最有前途和最直接的组合。特别地，以薄膜形式实现纯离子和混合离子/电子导体（MIEC）可以使多个固态器件（例如，固体氧化物燃料电池（SOFC））小型化。在这项工作中，我们将介绍通过使用微型和纳米制造技术在微型SOFC中实现新型纳米离子概念的方法。我们将特别关注晶界对界面主导材料（例如薄膜）中传质性能的贡献。晶界工程将作为减少与电解质相关的电阻，甚至控制MIEC材料的固有传输性质和性能的强大工具而被展示。

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《Ionic conducting oxide thin films》|2015年|11-16|共6页
会议地点 Phoenix AZ(US)
作者
A. Tarancon; A. Morata; D. Pla; A. M. Saranya; F. Chiabrera; I. Garbayo; A. Cavallaro; J. Canales-Vazquez; J. A. Kilner; M. Burriel;
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Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain;

Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain;

Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain;

Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain;

Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain;

Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain,Electrochemical Materials, ETH Zurich, CH-8093 Zurich, Switzerland;

Department of Materials, Imperial College London, London, SW7 2AZ, UK;

Instituto Energias Renovables, Universidad Castilla-La Mancha, 02071 Albacete, Spain;

Department of Materials, Imperial College London, London, SW7 2AZ, UK,Hydrogen Production Division, International Institute for Carbon-Neutral Energy Research (I2CNER), Fukuoka 819-0395, Japan;

Department of Advanced Materials for Energy Applications, Catalonia Institute for Energy Research (IREC), 08930 Sant Adria del Besos, Barcelona, Spain,Laboratoire des Materiaux et du Genie Physique (LMGP), CNRS - Grenoble INP, 38016 GRENOBLE Cedex 1, France;

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1. Thin Films: Engineering Mixed Ionic Electronic Conduction in La0.8Sr0.2MnO3+δ Nanostructures through Fast Grain Boundary Oxygen Diffusivity (Adv. Energy Mater. 11/2015) [J] . Aruppukottai M. Saranya, Dolors Pla, Alex Morata, Advanced energy materials . 2015,第11期

机译：薄膜：通过快速晶界氧扩散，在La0.8Sr0.2MnO3 +δ纳米结构中工程混合离子电子传导（Adv。Energy Mater。11/2015）
2. Electrical conduction of intrinsic grain and grain boundary in Mn-Co-Ni-0 thin film thermistors: Grain size influence [J] . L He, Z. Y. Ling Journal of Applied Physics . 2011,第9期

机译：Mn-Co-Ni-0薄膜热敏电阻中本征和晶界的导电：晶粒尺寸的影响
3. Engineering Mixed Ionic Electronic Conduction in La0.8Sr0.2MnO3+δ Nanostructures through Fast Grain Boundary Oxygen Diffusivity [J] . Aruppukottai M. Saranya, Dolors Pla, Alex Morata, Advanced energy materials . 2015,第11期

机译：La0.8Sr0.2MnO3 +δ纳米结构中通过快速晶界氧扩散技术工程混合离子电子传导
4. Grain Boundary Engineering to Improve Ionic Conduction in Thin Films for micro-SOFCs [C] . A. Tarancon, A. Morata, D. Pla, Meeting of the Electrochemical Society . 2015

机译：晶界工程改善微型SOFC薄膜离子传导
5. Investigation into the impact of grain boundaries, film interface, and crystallographic orientation on the ionic conductivity of thin film gadolinium-doped ceria. [D] . Swanson, Matthew M. 2010

机译：研究晶界，膜界面和晶体学取向对掺杂g的二氧化铈薄膜离子电导率的影响。
6. Proton Conduction in Grain-Boundary-Free Oxygen-Deficient BaFeO2.5+δ Thin Films [O] . Alexander Benes, Alan Molinari, Ralf Witte, 2018

机译：晶界无氧的BaFeO2.5 +δ薄膜中的质子传导
7. Engineering the grain boundary network of thin films via ion-irradiation: Towards improved electromigration resistance [O] . Huan Ma, Fabio La Mattina, Ivan Shorubalko, 2017

机译：通过离子辐射工程薄膜晶界网络：促进电迁移性
8. Enhanced ionic conduction at the film/substrate interface in LiI thin films grown on sapphire(0001) [R] . Lubben, D. , Modine, F. A. 1993

机译：在蓝宝石（0001）上生长的LiI薄膜中的薄膜/基板界面处的增强的离子传导

Grain Boundary Engineering to Improve Ionic Conduction in Thin Films for micro-SOFCs

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