應變調控柔性電子器件磁電性質的研究進展

郭琦; 王志成; 徐曉光; 姜勇

doi:10.13374/j.issn2095-9389.2017.12.001

應變調控柔性電子器件磁電性質的研究進展

doi: 10.13374/j.issn2095-9389.2017.12.001

北京科技大學材料科學與工程學院, 北京 100083

詳細信息

中圖分類號: O484
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出版歷程
- 收稿日期: 2017-07-12

Effect of strain on the magnetoelectric property of flexible electronics devices

School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China

摘要

摘要: 柔性電子器件具有獨特的形狀可塑性，因而引起了人們極大的研究熱情.柔性電子器件在未來或將成為下一代電子器件的重要分支，在電子顯示、二極管、生物醫療器件、太陽能電池等領域有著廣闊的發展前景.近些年，許多研究人員將柔性技術與自旋電子學相結合，開始探索應變對于生長在柔性襯底上的磁電異質結磁電性質的影響，通過改變柔性襯底的曲率等手段調控器件的磁電效應.相關基礎研究為磁存儲器、磁傳感器、非易失性阻變存儲器等電子器件的研究開辟了新思路.
- 柔性電子 /
- 自旋電子學 /
- 磁電異質結 /
- 應變
Abstract: Flexible electronic devices have attracted great interest owing to the advantages of flexible substrates as well as its arbitrary surface geometries, which may be one key branch of next-generation electronic devices, including paper-like electronic displays, light-emitting diodes, biointegrated medical devices, and solar cells. In recent years, some researchers have combined flexible techniques with spintronics to explore the effect of strain on magnetoelectric heterojunctions grown on flexible substrates and to control the magnetic and electric properties by changing the curvature of the substrate. These studies pave the path for the designing electronic devices, including magnetic storage devices, magnetic sensors, and non-volatile resistance memory.
- flexible electronics /
- spintronics /
- magnetoelectric hybridstructures /
- strain

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參考文獻(42)

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