1 research outputs found
Small Molecule-Modified Hole Transport Layer Targeting Low Turn-On-Voltage, Bright, and Efficient Full-Color Quantum Dot Light Emitting Diodes
For
an organic–inorganic hybrid quantum dot light-emitting diode
(QD-LED), enhancing hole injection into the emitter for charge balance
is a priority to achieve efficient device performance. Aiming at this,
we employ <i>N</i>,<i>N</i>′-bisÂ(3-methylphenyl)-<i>N</i>,<i>N</i>′-bisÂ(phenyl)Âbenzidine (TPD)
as the additional hole transport material which was mixed with polyÂ(9-vinylcarbazole)
(PVK) to form a composite hole transport layer (HTL) or was employed
to construct a TPD/PVK bilayer structure. Enabled by this TPD modification,
the green QD-LED (at a wavelength of 515 nm) exhibits a subband gap
turn-on voltage of 2.3 V and a highest luminance up to 56 157
cd/m<sup>2</sup>. Meanwhile, such TPD modification is also beneficial
to acquire efficient blue and red QD-LEDs. In particular, the external
quantum efficiencies (EQEs) for these optimized full-color QD-LEDs
are 8.62, 9.22, and 13.40%, which are 3–4 times higher than
those of their pure PVK-based counterparts. Revealed by the electrochemical
impedance spectroscopy, the improved electroluminescent efficiency
is ascribable to the reductions of recombination resistance and charge-transfer
resistance. The prepared QD-LEDs surpass the EQE values achieved in
previous reports, considering devices with small-molecule-modified
HTLs. This work offers a general but simple and very effective approach
to realize the low turn-on-voltage, bright, and efficient full-color
QD-LEDs via this solution-processable HTL modification