“…Recently, oxide-based photonic platforms relying on aluminum oxide (Al 2 O 3 ), with an ultra-large optical band gap of up to ∼7.6 eV, have attracted considerable attention as paradigm-shifting platforms for various transparent optoelectronic devices. − The realization of low-loss Al 2 O 3 waveguides, with an extended wavelength of up to 220 nm and substantially lower transmission losses compared to silicon nitride (Si 3 N 4 )-based waveguides, , is highly encouraging and paves the way for an integrated transparent oxide-based photonic platform across the visible wavelength region. Undeniably, such a platform would also allow the direct growth of conventional group-III–V-based light-emitting devices without the need for tedious photoelectrochemical etching for substrate removal and wafer bonding as in the case of heterogeneous integration on silicon-based platforms. , The eventual realization of a transparent all-oxide-based photonic platform would find promising applications in next-generation augmented-reality displays, smart goggles, smart windows, head-up displays, and other see-through devices. − This would be the case particularly where large-band-gap DUV photodetectors could be integrated as monitoring sensors for harmful ultraviolet-C (UVC) radiation (i.e., wavelengths of 100–280 nm) coming from flames and other man-made sources (e.g., mercury lamps, welding torches, and disinfection lamps), while maintaining high transparency across the visible wavelength region.…”