用于热释电传感器的激光加工铌酸锂晶片

IF 22.7 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Infomat Pub Date : 2024-05-23 DOI:10.1002/inf2.12557
Di Xin, Jing Han, Wei Song, Wenbin Han, Meng Wang, Zhimeng Li, Yunwu Zhang, Yang Li, Hong Liu, Xiaoyan Liu, Dehui Sun, Weijia Zhou
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引用次数: 0

摘要

在过去的几十年里,热释电传感器因其突出的特点而受到广泛关注。然而,低电输出阻碍了它们的有效性。本研究采用激光加工铌酸锂(LPLN)晶片来改善温度-电压响应。这些经过加工的晶片可用于构建热释电传感器和人机界面。激光诱导氧气逸出并形成氧空位,从而增强了铌酸锂(LN)表面的电荷传输能力。因此,电极聚集了更多的电荷,使 LPLN 晶圆上的热释电电压比 LN 晶圆高 1.3 倍。在人机界面方面,传感器阵列可以识别各种模式的触觉信息,温度预警系统运行良好。因此,激光改性方法有望提高热释电器件在人机界面中的应用性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Laser-processed lithium niobate wafer for pyroelectric sensor

Laser-processed lithium niobate wafer for pyroelectric sensor

Laser-processed lithium niobate wafer for pyroelectric sensor

During the past few decades, pyroelectric sensors have attracted extensive attention due to their prominent features. However, their effectiveness is hindered by low electric output. In this study, the laser processed lithium niobate (LPLN) wafers are fabricated to improve the temperature–voltage response. These processed wafers are utilized to construct pyroelectric sensors as well as human–machine interfaces. The laser induces escape of oxygen and the formation of oxygen vacancies, which enhance the charge transport capability on the surface of lithium niobate (LN). Therefore, the electrodes gather an increased quantity of charges, increasing the pyroelectric voltage on the LPLN wafers to a 1.3 times higher voltage than that of LN wafers. For the human–machine interfaces, tactile information in various modes can be recognized by a sensor array and the temperature warning system operates well. Therefore, the laser modification approach is promising to enhance the performance of pyroelectric devices for applications in human–machine interfaces.

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来源期刊
Infomat
Infomat MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
37.70
自引率
3.10%
发文量
111
审稿时长
8 weeks
期刊介绍: InfoMat, an interdisciplinary and open-access journal, caters to the growing scientific interest in novel materials with unique electrical, optical, and magnetic properties, focusing on their applications in the rapid advancement of information technology. The journal serves as a high-quality platform for researchers across diverse scientific areas to share their findings, critical opinions, and foster collaboration between the materials science and information technology communities.
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