用扫描热显微镜对多层陶瓷电容器中的电热效应进行高分辨率空间映射

IF 7 3区材料科学 Q1 ENERGY & FUELS

Journal of Physics-Energy Pub Date : 2023-09-08 DOI:10.1088/2515-7655/acf7f1

Olivia E Baxter, Amit Kumar, J. M. Gregg, R. McQuaid

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引用次数: 0

摘要

扫描热显微镜(SThM)是一种基于原子力显微镜的纳米尺度动态温度分布图的强大平台。然而，到目前为止，使用这种技术对电热(EC)材料的温度变化的空间成像非常有限。我们以Kar-Narayan等人(2013年苹果公司)的先前工作为基础。理论物理。Lett. 102 032903)和Shan等人(2020 Nano Energy 67 104203)表明，SThM可用于在微观长度尺度上对EC温度变化进行空间映射，这在商业上获得的多层陶瓷电容器中得到了证明。在我们的方法中，EC响应是在点对点距离小至125纳米的离散位置测量的，允许重建加热和冷却的空间地图，以及它们的时间演变。该技术提供了一种研究亚微米尺度EC响应的方法，这是更常用的红外热成像方法无法轻易获得的。

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High resolution spatial mapping of the electrocaloric effect in a multilayer ceramic capacitor using scanning thermal microscopy

Scanning thermal microscopy (SThM) is emerging as a powerful atomic force microscope based platform for mapping dynamic temperature distributions on the nanoscale. To date, however, spatial imaging of temperature changes in electrocaloric (EC) materials using this technique has been very limited. We build on the prior works of Kar-Narayan et al (2013 Appl. Phys. Lett. 102 032903) and Shan et al (2020 Nano Energy 67 104203) to show that SThM can be used to spatially map EC temperature changes on microscopic length scales, here demonstrated in a commercially obtained multilayer ceramic capacitor. In our approach, the EC response is measured at discrete locations with point-to-point separation as small as 125 nm, allowing for reconstruction of spatial maps of heating and cooling, as well as their temporal evolution. This technique offers a means to investigate EC responses at sub-micron length scales, which cannot easily be accessed by the more commonly used infrared thermal imaging approaches.

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来源期刊

Journal of Physics-Energy Multiple-

CiteScore

10.90

自引率

1.40%

发文量

期刊介绍： The Journal of Physics-Energy is an interdisciplinary and fully open-access publication dedicated to setting the agenda for the identification and dissemination of the most exciting and significant advancements in all realms of energy-related research. Committed to the principles of open science, JPhys Energy is designed to maximize the exchange of knowledge between both established and emerging communities, thereby fostering a collaborative and inclusive environment for the advancement of energy research.