https://onlinelibrary.wiley.com/doi/abs/10.1002/adom.201801631

Narrow-band luminescence materials used in white light-emitting diodes (WLEDs) have demonstrated a great potential to increase the maximum accessible color gamut, improve the color rendition, or enhance the visual luminous efficacy for illumination and display devices. So far, the discovery of narrow-band rare earth doped phosphors for emerging applications remains challenging owing to the limited systems in use and the broadening effect of 4f–5d transition. Here, two narrow-band cyan-emitting phosphors with the UCr₄C₄-related type structure, RbNa₂K(Li₃SiO₄)₄:Eu²⁺ (RNKLSO:Eu²⁺) and CsNa₂K(Li₃SiO₄)₄:Eu²⁺ (CNKLSO:Eu²⁺), are reported. The narrow-band emission results from the highly condensed network and a cube-like site for the activator (Eu²⁺). The emission peak assignments are investigated, and the variations of luminescence behavior with compositional changes of alkali cations are elaborated in detail. RNKLSO:8% Eu²⁺ (95%@250 °C of the integrated emission intensity at 25 °C) shows better thermal stability than that of CNKLSO:8% Eu²⁺ (79%@250 °C), which can be explained by the thermally activated crossover process represented in the configurational coordinate diagram. The optical properties of the as-fabricated WLEDs are studied and demonstrate potential with tunable properties for the full spectrum phosphor-converted LEDs. These findings in UCr₄C₄-type phases help shedding light on new avenues for fabricating new and totally unexpected narrow-emitting phosphors with versatile applications.