Charge injection/extraction has been a crucial issue to achieve high efficiency in optoelectronics including organic light emitting diodes (OLEDs) and solar cells (OSCs). Transition metal oxides (TMOs) including MoO_x have been well used as hole injection layers (HILs) because their conduction band minimum levels (E_CBM) consisting of vacant metal d-orbitals have good energy alignments with the HOMO levels of organic materials. However, the low-temperature-fabricated TMOs exhibit poor electrical properties owing to their orbital disordering, thus, only several-nanometers-thick TMO layers are applicable to OLEDs to avoid unwanted series resistance. While, we focused on amorphous oxide semiconductors (AOSs) because they have a variety of advantages such as high transparency, large mobility, good flexibility, and low-temperature process. However, conventional AOSs have relatively shallow E_CBM of ~4.5 eV that is not suitable to HIL. Therefore, it would be attractive if the AOS material with deep E_CBM is realized.
In this study, we successfully fabricated a new AOS material for HIL, amorphous In-Mo-O (a-IMO), with a large Hall mobility of ~1 cm²/Vs, very deep E_CBM of 5.6 eV that is close to the HOMO levels of the conventional organic materials in OLEDs/OSCs. Consequently, the OLED using a very thick a-IMO of ~100 nm as a HIL exhibits no operating voltage shift compared to that using a ~5 nm thick a-IMO. Furthermore, a-IMO exhibits very strong chemical stability against a variety of solvents such as water, toluene and DMSO. These results suggest that a-IMO is a very promising material that can improve the leakage-current issue, production yield and optical optimization in conventional organic optoelectronics.