# Discovery of room temperature ferromagnetism in metal-free organic   semiconductors

**Authors:** Qinglin Jiang, Jiang Zhang, Zhongquan Mao, Yao Yao, Duokai Zhao,, Wenqiang Zhang, Jiadong Zhou, Nan Zheng, Huanhuan Zhang, Manlin Zhao, Yong, Wang, Xiaolong Li, Dehua Hu, Yuguang Ma

arXiv: 1906.07531 · 2019-07-30

## TL;DR

This study reports the discovery of room temperature ferromagnetism in a metal-free organic semiconductor, demonstrating long-range magnetic order in materials traditionally considered nonmagnetic.

## Contribution

It introduces a novel method to induce ferromagnetism in organic semiconductors at room temperature, expanding the potential for organic magnetic devices.

## Key findings

- Ferromagnetism observed above 400 K in organic semiconductor
- Saturated magnetization of 0.48 μB per molecule
- Ferromagnetism originates from π orbitals of radicals

## Abstract

Creating magnetic semiconductors that work at warm circumstance is still a great challenge in the physical sciences. Here, we report the discovery of ferromagnetism in the metal-free perylene diimide semiconductor, whose Curie temperature is higher than 400 Kelvin. A solvothermal approach is used to reduce and dissolve the rigid-backbone perylene diimide crystallites, and radical anion aggregates were fabricated by the subsequent self-assembly and oxidation process. Magnetic measurements exhibit the ferromagnetic ordering with the saturated magnetization of 0.48 $\mu_{\rm B}$ per molecule and the appreciable magnetic anisotropy. X-ray magnetic circular dichroism spectra suggest the ferromagnetism stems from $\pi$ orbitals of radicals. Our findings unambitiously demonstrate the long-range ferromagnetic ordering can survive at room temperature in organic semiconductors, although which are intuitively regarded to be nonmagnetic.

---
Source: https://tomesphere.com/paper/1906.07531