Highlights •     We demonstrated an efficient, ITO-free, and inverted green phosphorescent organic light-emitting diodes (PHOLEDs). •     The PHOLED exhibited a maximum luminance of 280,000 cd/m2 at 8 V. •     The current efficiency of 81.4 cd/A and external quantum efficiency of 22.4% of PHOLED were achieved. •     The WAW showed the sheet resistance of 3.5 Ω/sq and the optical transmittance of ∼80% in visible range. •     The interface barrier of WAW/BPhen:CS2CO3 is 0.048 eV by electrical characterization.

Optical microscopy with white light illumination has been employed when obtaining exfoliated monolayer hexagonal boron nitride (1L hBN) films from a large number of randomly placed films on a substrate. However, real-time observation of 1L hBN using a color camera under white light illumination remains challenging since hBN is transparent in the visible wavelength range. The poor optical constant of 1L hBN films in microphotographs is significantly improved using a Si substrate coated with a SiNx thin-film (SiNx/Si). When observing hBN thin films on SiNx/Si using a color digital camera in an optical microscope under white light illumination, the clarity of the captured images depends on the thickness of the SiNx film (d). For direct real-time observation, the d was optimized based on quantitative chromatic studies tailored to Bayer filters of a color image sensor. Through image simulation, it was determined that the color difference between 1L hBN and the bare substrate is maximized at d = 59 or 70 nm, which was experimentally verified. The SiNx/Si with optimized d values visualized 1L hBN films without requiring significant contrast enhancement via image processing under white light illumination in real-time. Furthermore, the captured color photographs facilitate the reliable determination of the number of layers in few-layer hBN films using the contrast of the green channel of the images.