How to manipulate intermolecular exchange interaction to achieve long-range spin ordering? The answer to this question is of great importance in understanding and modulating magnetic behavior at the microscopic scale and in developing new macroscopic magnetic materials and devices.
However, temperature and environment play a decisive role in molecular magnetic behavior and spin ordering. At high temperatures, thermal uplift disrupts the spin ordering and disables intermolecular exchange interactions.
According to the Mermin-Wagner theory prediction, there is no long-range spontaneous magnetic ordering in two-dimensional systems. Therefore, realizing two-dimensional room-temperature ferromagnetic molecular materials still remains to be a challenge in this field. If solved, it will be vital for understanding the nature of magnetism.
To address this issue, a research group led by Prof. WU Changzheng from the Key Laboratory of Precision and Intelligent Chemistry of the University of Science and Technology of China (USTC) constructed room-temperature long-range ferromagnetic order and fabricated a molecular monolayer of honeycomb-like cobaltocene (Co(Cp)2), a simplified form of Co(C5H5)2) in a confined van der Waals interlayer space.
Honeycomb cell of a confined Co(Cp)2 monolayer (Image by USTC)
Researchers developed the vibronic superexchange interaction between Co(Cp)2 molecules and S atoms based on the dynamic charge transfer at the organic-inorganic (Co(Cp)2/SnS2) superlattice interface, and realized a long-range ferromagnetic order between organic molecules, from which they obtained the two-dimensional ferromagnetic molecular layers at high transition temperature (> 400 K) and large saturation magnetization (4 emu.g-1) in a weak field.
Researchers also managed to characterize the orientation of individual Co(Cp)2 molecules confined between SnS2 layers and structural assembly of honeycomb-like monolayer molecule by scanning probe microscopy coupled with scanning tunnelling microscopy and atomic force microscopy.
The electron clouds of neighboring Co(Cp)2 molecules merged with each other to form delocalized electrons, which meditated the spin-exchange interactions between Co(Cp)2 molecules.
The related research results were published in Nature Physics.
This work realized a new structure of magnetic solids by modulating the molecular spin order, which is expected to provide better solutions for applications such as electronics, information storage and quantum computing.
paper link: https://www.nature.com/articles/s41567-023-02312-z
(written by HUANG Rui, edited by HUANG Rui, USTC News Center)