In the nearly 30 years since the first rare earth SMMs were reported, tremendous progress has been made in single-molecule magnets, especially in single-nuclear and bi-nuclear rare earth SMMs, where some molecules have even been able to exhibit hysteresis lines above liquid
In this review, the recent progress in rare earth SMMs represented by mononuclear and dinuclear complexes is highlighted, especially for the modulation of magnetic anisotropy, effective energy barrier (Ueff) and
The fact that this molecule can show a memory effect on dilution, almost at a molecular level, opens up new possibilities for SCO systems doubling up as single-molecule magnets at elevated temperatures in the foreseeable future.
In this review, the recent progress in rare earth SMMs represented by mononuclear and dinuclear complexes is highlighted, especially for the modulation of magnetic anisotropy, effective energy barrier (Ueff) and blocking temperature (TB).
This critical review provides a broad overview of recent progress in the design and development of rare-earth-based nanomaterials.
Here, we present the Rare-earth based single-molecule magnets are promising candidates for magnetic information storage including qubits as their large magnetic moments are carried by localized 4 f electrons.
In the nearly 30 years since the first rare earth SMMs were reported, tremendous progress has been made in single-molecule magnets, especially in single-nuclear and bi-nuclear rare earth SMMs, where some molecules have even been able to exhibit hysteresis lines above liquid nitrogen temperatures.
A novel tetrazine-bridged molecule forms a powerful, stable magnet ideal for next-gen data storage. Magnets formed from a single molecule are of particular interest in data storage, since the ability to store a bit on every molecule could vastly increase the storage capacity of computers.
Single-molecule magnets (SMMs) are paramagnetic molecules that can be magnetized below a certain temperature and have potential applications in high-density information storage, magnetic...
Abstract: The nanostructuring of single-molecule mag-nets (SMMs) on substrates, in nanotubes and periodic frameworks is highly desired for the future magnetic recording devices. However, the ability to organize SMMs into long-range ordered arrays in these systems is still lacking.
Rare-earth based single-molecule magnets are promising candidates for magnetic information storage including qubits as their large magnetic moments are carried by localized $4f$ electrons. This shielding from the environment in turn hampers a direct electronic access to the magnetic moment.
In this Perspective, we reviewed recent advancements of SMMs on suitable solid surfaces that can retain and even enhance their magnetic properties. We discuss promising SMMs and the relevant physical parameters that contribute to their magnetic properties.
In this Perspective, we reviewed recent advancements of SMMs on suitable solid surfaces that can retain and even enhance their magnetic properties. We discuss promising SMMs and the relevant physical parameters
A novel tetrazine-bridged molecule forms a powerful, stable magnet ideal for next-gen data storage. Magnets formed from a single molecule are of particular interest in data storage, since the ability to store a bit on every
