Efficient emission from various donor−acceptor quinolines with an ethynyl linkage (PnQ), which are known
as efficient electrogenerated chemiluminescent molecules, was observed with time-resolved fluorescence
measurement during the pulse radiolysis in benzene. On the basis of the transient absorption and emission
measurements, and steady-state measurements, the formation of PnQ in the singlet excited state can be
interpreted by charge recombination between the PnQ radical cation and the PnQ radical anion which are
generated initially from the radiolytic reaction in benzene. The strong electronic coupling between the donor
and acceptor through conjugation is responsible for the efficient emission during the pulse radiolysis of PnQ
in benzene. It is suggested that the positive and negative charges are localized on the donor and acceptor
moieties in the radical cation and anion, respectively. This mechanism is reasonably explained by the
relationship between the annihilation enthalpy changes and singlet excitation energies of PnQ. The formation
of the intramolecular charge transfer state is assumed for PnQ in the singlet excited state with a strong
electron donating substituent. The emission from PnQ is suggested to originate from PnQ in the singlet
excited state formed from the charge recombination between the PnQ radical cation and the PnQ radical
anion during the pulse radiolysis. This is strong evidence for the efficient electrogenerated chemiluminescence
of PnQ.
A series of bipolar OLED materials were subjected to pulsed radiolysis experiments to determine their transient absorption and lifetime profiles of the independently in situ generated radical cations and anions in solutions. Moreover, their emission behaviors from the charge recombination of their radical ions were also determined by the pulse radiolysis method. It was found the absorption bands in doubly ortho-linked quinoxaline/diphenylfluorene hybrids 1a-e are red-shifted progressively with increasing electron-donating nature at the C5 and C8 positions of the quinoxaline template. The incipient radical anions in 1a-e are mainly localized on the quinoxaline heterocyclic moiety, whereas the incipient radical cations are mainly distributed onto the attached electron-donating groups at the C5 and C8 positions of the quinoxaline template. For other doubly ortho-linked cis-stilbene derivatives 3d, 3f, and 4f, the radical anions are mainly localized on the cis-stilbene central moiety and the radical cation is mainly distributed onto both para substituents of the cis-stilbene templates. It was also shown that there is a correlation between their optoelectronic emission efficiencies and the radiolysis induced emission intensities. In addition, the charge transporting behaviors within an OLED device were found to show the relationship with transient absorption half-lives (tau(1/2)) of the radical ions. Charge recombination mechanisms in both the OLED and pulsed radiolysis experiments were proposed to rationalize these observations, allowing us to establish some guidelines for an ultimate molecular design of ideal bipolar optoelectronic materials with a judicious choice of local charge appendages in the optoelectronic templates.
Formation of radical cation and charge-transfer complex of [3n]cyclophanes (n = 3, 5, 6) was investigated by transient absorption spectroscopy during pulse radiolysis. Radical cations of [3n]cyclophanes showed the charge resonance band around 700 nm which exhibited a blue-shift as the number of trimethylene bridges increased, indicating formation of highly stabilized intramolecular dimer radical cation of [3n]cyclophanes. The absorption peak of the charge-transfer complex with chlorine atom also showed the shift in accord with the oxidation potential of [3n]cyclophanes.
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