Magnetoresistance Effect and the Applications for Organic Spin Valves Using Molecular Spacers

Overview

Journal Materials (Basel)

Publisher MDPI

Date 2018 May 13

PMID 29751514

Citations 2

Authors

Xiannian Yao

Qingqing Duan

Junwei Tong

Yufang Chang

Lianqun Zhou

Gaowu Qin

Xianmin Zhang

Affiliations

Soon will be listed here.

Abstract

Organic spin devices utilizing the properties of both spin and charge inherent in electrons have attracted extensive research interest in the field of future electronic device development. In the last decade, magnetoresistance effects, including giant magetoresistance and tunneling magnetoresistance, have been observed in organic spintronics. Significant progress has been made in understanding spin-dependent transport phenomena, such as spin injection or tunneling, manipulation, and detection in organic spintronics. However, to date, materials that are effective for preparing organic spin devices for commercial applications are still lacking. In this report, we introduce basic knowledge of the fabrication and evaluation of organic spin devices, and review some remarkable applications for organic spin valves using molecular spacers. The current bottlenecks that hinder further enhancement for the performance of organic spin devices is also discussed. This report presents some research ideas for designing organic spin devices operated at room temperature.

Citing Articles

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Gu X, Guo L, Qin Y, Yang T, Meng K, Hu S Precis Chem. 2024; 2(1):1-13.

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