Chemical unit co-substitution for a new far-red-emitting phosphor Ca3-6y(NaLu)3yLiSbO6:Mn4+ to achieve high quantum efficiency and superb thermal stability

Zhiyuan Li, Xuhui Zhang, Niansi Fan, Rui Guo*, Eric H. Amador, Qianqian Gao, Hongmei Yu*, Huibin Zheng*, Lan Luo, Li Wang, Yuhua Xiong, Wei Chen*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

15 Citations (Scopus)

Abstract

The discovery of Mn4+-doped red phosphors with a high quantum efficiency (QE) and good thermal stability is of great interest for plant cultivation lighting. Here, for the first time, a new highly efficient and thermally stable far-red-emitting phosphor Ca3-6y(NaLu)3yLiSbO6:Mn4+ (CNULS:Mn4+) is reported. When a far-red-emitting phosphor Ca3LiSbO6:Mn4+ (CLS:Mn4+) was prepared via the solid-state reaction method, its maximum internal and external QEs are only 39.5% and 23.1%, respectively. Through the chemical unit co-substitution of [Na+−Lu3+] for [Ca2+−Ca2+] in CLS:Mn4+, its luminescence properties can be improved tremendously and the internal and external QEs for the substitution amount of y = 3% are as high as 80.1% and 47.4%, respectively. The large luminescence enhancement is attributed to the increase of structural rigidity induced by lattice contraction. The CNULS:Mn4+ phosphor exhibits excellent thermal stability with the emission intensity at 423 K remaining 87% of the value at 298 K. The LED device fabricated with the CNULS:Mn4+ (y = 3%) phosphor can produce bright and stable far-red emission, which matches well with the absorption spectrum of phytochrome PFR. These results suggest that the CNULS:Mn4+ phosphor could be a promising far-red-emitting converter for plant growth as well as solid-state lighting.

Original languageEnglish
Article number100193
JournalMaterials Today Advances
Volume12
DOIs
Publication statusPublished - Dec 2021
Externally publishedYes

Keywords

  • CaLiSbO:Mn
  • Chemical unit co-substitution
  • Luminescence properties
  • Plant cultivation lighting
  • Quantum efficiency
  • Red phosphor

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