Charge-Transfer Complexes: Halogen-Doped Anthracene as a Case of Study.
Simone GilioliRoberto GiovanardiCamilla FerrariMonica MontecchiAndrea GemelliAndrea SeveriniFabrizio RoncagliaAlberta CarellaFrancesco RossellaDavide VanossiAndrea MarchettiRaanan CarmieliLuca PasqualiFontanesi ClaudioPublished in: Chemistry (Weinheim an der Bergstrasse, Germany) (2024)
Charge transfer (CT) crystals exhibit unique electronic and magnetic properties with interesting applications. We present a rational and easy guide which allows to foresee the effective charge transfer co-crystal production and that is based on the comparison of the frontier molecular orbital (MO) energies of a donor and acceptor couple. For the sake of comparison, theoretical calculations have been carried out by using the cheap and fast PM6 semiempirical Hamiltonian and pure HF/cc-pVTZ level of the theory. The results are then compared with experimental results obtained both by chemical (bromine and iodine were used as the acceptor) and electrochemical doping (exploiting an original experimental set-up by this laboratory: the electrochemical transistor). Infra-red vibrational experimental results and theoretically calculated spectra are compared to assess both the effective donor-acceptor (D/A) charge-transfer and transport mechanism (giant IRAV polaron signature). XPS spectra have been collected (carbon (1 s) and iodine (3d 5/2 )) signals, yielding further evidence of the effective formation of the CT anthracene:iodine complex.
Keyphrases
- dual energy
- density functional theory
- computed tomography
- energy transfer
- molecularly imprinted
- image quality
- solar cells
- molecular dynamics
- gold nanoparticles
- contrast enhanced
- quantum dots
- molecular dynamics simulations
- ionic liquid
- positron emission tomography
- magnetic resonance imaging
- air pollution
- label free
- particulate matter
- magnetic resonance
- high resolution
- room temperature
- heavy metals
- risk assessment
- highly efficient
- rare case
- water soluble