The
thermodynamic properties and band gap energies were evaluated
for six ortho- and peri-fused polycyclic aromatic hydrocarbons (PAHs):
triphenylene; benzo[a]pyrene; benzo[e]pyrene; perylene; benzo[ghi]perylene; coronene.
The standard molar enthalpies of formation in the crystalline state
and the standard molar enthalpies of sublimation were measured by
high precision combustion calorimetry and Knudsen effusion methodology,
respectively. The combination of the molar enthalpies of formation
in the crystalline state with the respective enthalpies of sublimation
was used to evaluate the energetics of the progressive peri-fusion
of the aromatic moieties from triphenylene to coronene aiming to investigate
the hypothetical superaromaticity character of coronene. The linear
trend of the enthalpy of formation in crystalline and gaseous phases
in the series (from benzo[e]pyrene to coronene) is
an irrefutable indication of a non-superaromaticity character of coronene.
High accurate thermodynamic properties of sublimation (volatility,
enthalpy, and entropy of sublimation) were derived by the measurement
of vapor pressures as a function of temperature, using a Knudsen/quartz
crystal effusion methodology. Furthermore, the π-electronic
conjugation of these compounds was explored by evaluation of the optical
band gaps along with this series of compounds. The morphology of perylene,
benzo[ghi]perylene, and coronene thin films, deposited
by physical vapor deposition onto transparent conductive oxide substrates
(ITO and FTO), was used to analyze the nucleation and growth mechanisms.
The morphologies observed were found to be related to the cohesive
energy and entropy of the bulk.
The molecular and supramolecular structure and energetics of tetracene and rubrene were investigated by a combined experimental and theoretical study. Accurate equilibrium vapour pressures at various temperatures were measured for both compounds. For rubrene the energetic analysis evidences lower crystal packing efficiency, strong molecular destabilization and confirms the non‐planar twisted equilibrium structure in the gas phase. The results also indicate that phenyl internal rotation in rubrene is highly hindered. The intra‐ and intermolecular interactions in crystal tetracene and rubrene were evaluated by computational methods. The representative stacked dimer of the tetracene⋅⋅⋅tetracene interaction in rubrene has lower ionization energy than the one modelling the same interaction in tetracene, due to stronger cation⋅⋅⋅π interactions in the cation‐radical of rubrene. Charge distribution in the cation dimer is symmetrical in rubrene, whereas in tetracene it is largely localized on the C−H⋅⋅⋅π donor partner of the herringbone dimer. These findings highlight the impact of cation⋅⋅⋅π interactions on the semiconducting properties of OSCs.
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