Energy-Transfer-Enhanced Cr3+/Ni2+Co-doped Broadband Near-Infrared Phosphor for Fluorescence Thermometers and Near-Infrared Window Imaging

Here, near-infrared broad dual-band emission phosphors were achieved through energy transfer between Cr3+and Ni2+ions in the β-Ga2O3host. All samples co-doped with Cr3+and Ni2+exhibit dual-band emission covering 600–1700 nm under 430 nm excitation. Thanks to the doping of Cr3+ions, the emission intensity of Ga2O3:Cr3+, Ni2+phosphors has increased by about 2.4 times and the internal quantum efficiency has increased by 83.2% compared to Ga2O3:Ni2+phosphors. Meanwhile, when the fluorescence lifetime was monitored at 745 nm, an efficient energy transfer between Cr3+and Ni2+ions in the β-Ga2O3host was verified. Due to the significant differences in the emission temperature-sensitive properties of Cr3+and Ni2+ions, a thermometer was designed utilizing fluorescence intensity ratio technology, achieving a maximum relative sensitivity of 5.26% K–1, which surpasses most optical temperature measurement phosphors. This suggests that Ga2O3:Cr3+, Ni2+samples hold promise as potential candidates for optical thermometer materials. Additionally, the broadband near-infrared emission of the Ga2O3:Cr3+, Ni2+sample has been investigated for potential applications in component analysis and night vision, demonstrating its versatility for multifunctional applications.