Broadband, Enhanced, and Antithermally Quenched Near-Infrared Phosphors via a Cosubstitution Approach.
Qianrui MaTing WangWei GaoBitao LiuHao ZhangZhenzhen CuiHaihong GuoLiang XiuShaoqing WangZiyang LiLongchao GuoSiufung YuXue YuJianbei QiuJian-Bei QiuPublished in: Inorganic chemistry (2021)
Wearable biosensing and food safety inspection devices with high thermal stability, high brightness, and broad near-infrared (NIR) phosphor-converted light-emitting diodes (pc-LEDs) could accelerate the next-generation NIR light applications. In this work, NIR La3-xGdxGa5GeO14:Cr3+ (x = 0 to 1.5) phosphors were successfully fabricated by a high-temperature solid-state method. Here, by doping Gd3+ ions into the La3+ sites in the La3Ga5GeO14 matrix, a 7.9-fold increase in the photoluminescence (PL) intensity of the Cr3+ ions, as well as a remarkably broadened full width at half-maximum (FWHM) of the corresponding PL spectra, is achieved. The enhancements in the PL, PLE intensity, and FWHM are attributed to the suppression of the nonradiative transition process of Cr3+ when Gd3+ ions are doped into the host, which can be demonstrated by the decay curves. Moreover, the La1.5Gd1.5Ga5GeO14:Cr3+ phosphor displays an abnormally negative thermal phenomenon that the integral PL intensity reaches 131% of the initial intensity when the ambient temperature increases to 160 °C. Finally, the broadband NIR pc-LED was fabricated based on the as-explored La1.5Gd1.5Ga5GeO14:Cr3+ phosphors combined with a 460 nm chip, and the potential applications for the broadband NIR pc-LEDs were discussed in detail.
Keyphrases
- light emitting
- energy transfer
- quantum dots
- photodynamic therapy
- pet ct
- drug release
- high intensity
- fluorescence imaging
- fluorescent probe
- solid state
- high temperature
- high speed
- air pollution
- drug delivery
- aqueous solution
- risk assessment
- blood pressure
- water soluble
- particulate matter
- highly efficient
- high throughput
- heart rate
- single cell