Development and Present Status of Organic Superconductors

Abstract: based on the two main requirements for the conductivity, namely, (1) a uniform segregated stacking of the same kind of component molecules, and (2) the fractional CT state (uniform partial CT) of the molecules. Since TTF•TCNQ has a low-dimensional segregated stacking, it showed a metal-insulator (MI) transition (Peierls transition) below about 60 K. For TTF•TCNQ, the Peierls transition occurs by the nesting of the one-dimensional Fermi surface causing lattice distortion associated with the strong electron-phon… Show more

“…In the past, pressure has been used to reduce the resistivity of these semiconductors, suggesting that oligoacences could be the first single component organic molecular crystals (OMC) to show “metallic” behavior . The idea that oligoacenes (particularly pentacene) under pressure are conductors is perpetuated in recent articles and reviews. , However, a high pressure optical study of pentacene up to ∼32 GPa showed no metallization due to condensation reactions, though a steady narrowing of the HOMO–LUMO band gap was observed until the molecular identity of the acene components was compromised.…”

Understanding the Structure and Electronic Properties of Molecular Crystals Under Pressure: Application of Dispersion Corrected DFT to Oligoacenes

“…In the past, pressure has been used to reduce the resistivity of these semiconductors, suggesting that oligoacences could be the first single component organic molecular crystals (OMC) to show “metallic” behavior . The idea that oligoacenes (particularly pentacene) under pressure are conductors is perpetuated in recent articles and reviews. , However, a high pressure optical study of pentacene up to ∼32 GPa showed no metallization due to condensation reactions, though a steady narrowing of the HOMO–LUMO band gap was observed until the molecular identity of the acene components was compromised.…”

Understanding the Structure and Electronic Properties of Molecular Crystals Under Pressure: Application of Dispersion Corrected DFT to Oligoacenes

“…The very fact of cocrystal formation largely depends on the match between the HOMO and LUMO energy levels of the donor and acceptor molecules and the geometry fit of coformers, in particular their size and planarity. The electronic properties of cocrystals depend on coformers; however, the supramolecular arrangement of the latter in single crystals is just as important, as it determines the overlap of their molecular orbitals, transfer integrals, and transport network. − The most illustrative examples involve different properties of CT complexes, containing tetrathiafulvalene derivatives as donors and tetracyanoquinodimethane (TCNQ) derivatives as acceptors, which possess a different stacking mode: the polymorphs with segregated stacks have metallic conductivity, while the other modifications with alternating donor and acceptor components are insulators or semiconductors. − However, even smaller structural differences in polymorphic cocrystals with alternating stacks, though having similar HOMO and LUMO energies, may involve a significant variation of charge-transfer and transport properties …”

New Charge Transfer Cocrystals of F₂TCNQ with Polycyclic Aromatic Hydrocarbons: Acceptor–Acceptor Interactions and Their Contribution to Supramolecular Arrangement and Charge Transfer

Spectroelectrochemical characterization of conducting polymers from star-shaped carbazole-triphenylamine compounds