Litcius/Paper detail

Multi-peaked broad-band red phosphor Y<sub>3</sub>Si<sub>6</sub>N<sub>11</sub>:Pr<sup>3+</sup>for white LEDs and temperature sensing

Dashuai Sun, Liangliang Zhang, Zhendong Hao, Hao Wu, Huajun Wu, Yongshi Luo, Lin Yang, Xia Zhang, Feng Liu, Jiahua Zhang

2020Dalton Transactions20 citationsDOI

Abstract

The indispensable broad-band red phosphors for LED lighting generally show a long emission tail for wavelengths longer than 650 nm, which consumes excitation energy but contributes little luminance. Here, we report, for the first time, a broad red emission band with a steep falling edge at 652 nm, formed of widely distributed 1D2 → 3H4 emission lines of Pr3+ in Y3Si6N11 due to a large Stark splitting of the 3H4 (930 cm-1) and 1D2 (725 cm-1) levels. The red emission exhibits a 43 nm bandwidth, which is the widest in Pr3+-doped phosphors reported so far. The red Y3Si6N11:Pr3+ phosphor was applied for the fabrication of 310 nm UV chip-based white LEDs, and a high color rendering index of 96 at a low correlated color temperature of 4188 K was achieved. Furthermore, a temperature-sensing scheme was proposed based on the temperature-dependent intensity ratios of the emission lines from the thermally coupled and large Stark splitting levels of the 1D2 state. Relative sensitivities as a function of temperature were studied in the range of 93-473 K. The findings of this study indicate that Y3Si6N11:Pr3+ is an attractive broad-band red phosphor for both high color rendering white LEDs and temperature sensing applications.

Topics & Concepts

PhosphorLight-emitting diodeBroad bandMaterials scienceWhite lightAnalytical Chemistry (journal)CrystallographyOptoelectronicsChemistryPhysicsOpticsChromatographyLuminescence Properties of Advanced MaterialsAdvanced Photocatalysis TechniquesInorganic Chemistry and Materials