Project description
Single-molecule magnets at unprecedented temperatures
Single-molecule magnets (SMMs) are a class of materials composed of individual molecules that exhibit magnetic behaviour at the molecular level. SMMs exhibit the unique ability of magnetic hysteresis, which means they can retain their magnetisation even in the absence of an external magnetic field. This property makes SMMs promising for potential applications in nanoscale devices. Funded by the European Research Council, the RadMag project aims to create innovative SMMs that can operate at higher temperatures by combining novel radical ligands. The project's success could revolutionise the field of SMMs and pave the way towards practical applications at higher temperatures.
Objective
Single-molecule magnets (SMMs) display magnetic hysteresis that is molecular in origin, and these materials have huge potential to be developed as nano-scale devices. The big challenge is to create SMMs that function without the need for liquid-helium cooling.
This project will develop new SMMs that combine the strong magnetic anisotropy of lanthanide ions with a series of novel radical ligands. Our innovative SMMs will have controllable molecular and electronic structures, which will ultimately enable hysteresis at unprecedented temperatures.
Highly unusual di- and tri-metallic Ln-SMMs are proposed in which the metals are bridged by radicals with heavy Group 15 (phosphorus-bismuth) and Group 16 (sulphur-tellurium) donor atoms. Trimetallic SMMs will also be based on hexaazatriphenylene (HAT) radicals, and dimetallic SMMs will also be based on nindigo radicals, both of which are nitrogen-donor ligands.
The SMM field is dominated by systems with diamagnetic ligands. Our radical ligands have never been used in SMM studies: their diffuse unpaired spin provides a way of switching off the quantum tunnelling mechanisms that otherwise prevent hysteresis. We will exploit the rich electrochemistry of the target ligands: heavy p-block radicals have huge spin densities on the donor atoms; HAT radicals can have up to three unpaired electrons; reduced or oxidized nindigo radicals allow access to redox-switchable SMMs. In the HAT-bridged SMMs, the use of ligands with more than one unpaired electron is unprecedented. The heavy p-block ligands are themselves are novel.
The PI’s approach to SMMs has already established new directions in lanthanide chemistry and in molecular magnetism. He now proposes a new, radical approach to SMMs with potential to re-define the state of the art, and to extend the frontiers of a vibrant multi-disciplinary field. Achieving the aims will provide a major step towards using SMMs for applications at practical temperatures.
Fields of science
Programme(s)
Funding Scheme
ERC-COG - Consolidator GrantHost institution
BN1 9RH Brighton
United Kingdom