Fullerides are chemical compounds containing fullerene anions. Common fullerides are derivatives of the most common fullerenes, i.e. C<sub>60</sub> and C<sub>70</sub>. The scope of the area is large because multiple charges are possible, i.e., [C<sub>60</sub>]<sup>nâÂÂ</sup> (n = 1, 2...6), and all fullerenes can be converted to fullerides. The suffix "-ide" implies their negatively charged nature.
Fullerides can be isolated as derivatives with a wide range of cations. Most heavily studied derivatives are those with alkali metals, but fullerides have been prepared with organic cations. Fullerides are typically dark colored solids that generally dissolve in polar organic solvents.
According to electronic structure calculations, the LUMO of C<sub>60</sub> is a triply degenerate orbital of t<sub>1u</sub> symmetry. Using the technique cyclic voltammetry, C<sub>60</sub> can be shown to undergo six reversible reductions starting at âÂÂ1 V referenced to the Fc<sup>+</sup>/Fc couple. Reduction causes only subtle changes in the structure and many derivatives exhibit disorder, which obscures these effects. Many fullerides are subject to JahnâÂÂTeller distortion. In certain cases, e.g. <nowiki>[</nowiki>PPN<nowiki>]</nowiki><sub>2</sub>C<sub>60</sub>, the structures are highly ordered and slight (10 pm) elongation of some CâÂÂC bonds is observed.
Fullerides have been prepared in various ways:
The fulleride salt ([K(crypt-222)]<sup>+</sup>)<sub>2</sub>[C<sub>60</sub>]<sup>2âÂÂ</sup> salt is synthesized by treating C<sub>60</sub> with metallic potassium in the presence of [2.2.2]cryptand.
Particular attention has been paid to alkali metal (Na<sup>+</sup>, K<sup>+</sup>, Rb<sup>+</sup>, Cs<sup>+</sup>) derivatives of C<sub>60</sub><sup>3âÂÂ</sup> because these compounds exhibit physical properties resulting from intercluster interactions such as metallic behavior. In contrast, in C<sub>60</sub>, the individual molecules interact only weakly, i.e. with essentially nonoverlapping bands. These alkali metal derivatives are sometimes viewed as arising by intercalation of the metal into C<sub>60</sub> lattice. Alternatively, these materials are viewed as n-doped fullerenes.
Alkali metal salts of this trianion are superconducting. In M<sub>3</sub>C<sub>60</sub> (M = Na, K, Rb), the M<sup>+</sup> ions occupy the interstitial holes in a lattice composed of ccp lattice composed of nearly spherical C<sub>60</sub> anions. In Cs<sub>3</sub>C<sub>60</sub>, the cages are arranged in a bcc lattice.
In 1991, it was revealed that potassium-doped C<sub>60</sub> becomes superconducting at . This was the highest transition temperature for a molecular superconductor. Since then, superconductivity has been reported in fullerene doped with various other alkali metals. It has been shown that the superconducting transition temperature in alkaline-metal-doped fullerene increases with the unit-cell volume V. As Cs<sup>+</sup> is the largest alkali ion, caesium-doped fullerene is an important material in this family. Superconductivity at has been reported in bulk Cs<sub>3</sub>C<sub>60</sub>, but only under applied pressure. The highest superconducting transition temperature of at ambient pressure is reported for Cs<sub>2</sub>RbC<sub>60</sub>.
The increase of transition temperature with the unit-cell volume had been believed to be evidence for the BCS mechanism of C<sub>60</sub> solid superconductivity, because inter C<sub>60</sub> separation can be related to an increase in the density of states on the Fermi level, N(õ<sub>F</sub>). Therefore, efforts have been made to increase the interfullerene separation, in particular, intercalating neutral molecules into the A<sub>3</sub>C<sub>60</sub> lattice to increase the interfullerene spacing while the valence of C<sub>60</sub> is kept unchanged. However, this ammoniation technique has revealed a new aspect of fullerene intercalation compounds: the Mott transition and the correlation between the orientation/orbital order of C<sub>60</sub> molecules and the magnetic structure.
Fourfold-reduced materials, i.e., those with the stoichiometry A<sub>4</sub>C<sub>60</sub>, are insulating, even though the t<sub>1u</sub> band is only partially filled. This apparent anomaly may be explained by the JahnâÂÂTeller effect, where spontaneous deformations of high-symmetry molecules induce the splitting of degenerate levels to gain the electronic energy. The JahnâÂÂTeller type electron-phonon interaction is strong enough in C<sub>60</sub> solids to destroy the band picture for particular valence states.
A narrow band or strongly correlated electronic system and degenerated ground states are relevant to explaining superconductivity in fulleride solids. When the interelectron repulsion U is greater than the bandwidth, an insulating localized electron ground state is produced in the simple MottâÂÂHubbard model. This explains the absence of superconductivity at ambient pressure in caesium-doped C<sub>60</sub> solids. Electron-correlation-driven localization of the t<sub>1u</sub> electrons exceeds the critical value, leading to the Mott insulator. The application of high pressure decreases the interfullerene spacing, therefore caesium-doped C<sub>60</sub> solids turn to metallic and superconducting.
A fully developed theory of C<sub>60</sub> solids superconductivity is lacking, but it has been widely accepted that strong electronic correlations and the JahnâÂÂTeller electronâÂÂphonon coupling produce local electron pairings that show a high transition temperature close to the insulatorâÂÂmetal transition.