Transition-metal
oxides
(TMO), such as molybdenum tri-oxide (MoO3), are promising
hole-injection electrode materials for organic electronics because of their
large work function and high conductivity. They are superior to the widely used
organic polymer PEDOT:PSS which causes device degradation. However, deposition
of MoO3 layers
from high-temperature sources is problematical for flexible organic-based
electronics.
Fig. 1
AFM image of a film of MoO3 nanoparticles
Kahn et al. have developed a low-temperature method to deposit TMO
films using solution-based processing of nanoparticles of MoO3 [1]. The nanoparticles, in
suspension in a solvent, are spin-coated onto the target substrate. The
surfactant is then easily removed by a short plasma treatment
(Fig. 1). The current-voltage characteristics of the
deposited MoO3 layers compare
well with thermally evaporated films, and are
better than PEDOT:PSS (Fig. 2). With the rapid growth
in the commercial applications of nanoparticles, this approach is
promising for large-area manufacturing.
Fig. 2
How hole-injection from ITO electrodes varies with different
charge-transport layers
