2 research outputs found
Waterproof Narrow-Band Fluoride Red Phosphor K<sub>2</sub>TiF<sub>6</sub>:Mn<sup>4+</sup> via Facile Superhydrophobic Surface Modification
With
unique and efficient narrow-band red emission and broadband blue light
absorption characteristics, Mn<sup>4+</sup>-activated fluoride red
phosphors have gained increasing attention in warm white LEDs (WLEDs)
and liquid crystal display (LCD) backlighting applications, whereas
the intrinsic hygroscopic nature of these phosphors have inevitably
limited their practical applications. Herein, a waterproof narrow-band
fluoride phosphor K<sub>2</sub>TiF<sub>6</sub>:Mn<sup>4+</sup> (KTF)
has been demonstrated via a facile superhydrophobic surface-modification
strategy. With the use of superhydrophobic surface modification with
octadecyltrimethoxysilane (ODTMS) on KTF surfaces, the moisture-resistance
performance and thermal stability of the phosphor KTF can be significantly
improved. Meanwhile, the absorption, and quantum efficiency did not
show obvious changes. The surface-modification processes and mechanism,
as well as moisture-resistance performances and luminescence properties,
of the phosphors have been carefully investigated. It was found that
the luminous efficiency (LE) of the modified KTF was maintained at
83.9% or 84.3% after being dispersed in water for 2 h or aged at high
temperature (85 Ā°C) and high humidity (85%) atmosphere (HTHH)
for 240 h, respectively. The WLEDs fabricated with modified KTF phosphor
showed excellent color rendition with lower color temperature (2736
K), higher color rendering index (CRI, Ra = 87.3, R9 = 80.6), and
high luminous efficiency (LE = 100.6 lm/W) at 300 mA. These results
indicate that hydrophobic silane coupling agent (SCA) surface modification
was a promising strategy for enhancing moisture resistance of humidity-sensitive
phosphors, exhibiting great potential for practical applications
Confining Mn<sup>2+</sup>-Doped Lead Halide Perovskite in ZeoliteāY as Ultrastable Orange-Red Phosphor Composites for White Light-Emitting Diodes
CsPbX<sub>3</sub> (X = Cl, Br, I) perovskite quantum dots (QDs) have emerged
as competitive candidate luminescent materials in the photoelectric
fields due to their superior luminescence properties. However, the
major drawback such as poor resistance to temperature, moisture, and
irradiation of light, especially for the red QDs with I<sup>ā</sup>, hinders their practical applications. Herein, we synthesized Mn<sup>2+</sup>-doped CsPbCl<sub>3</sub> embedded in the cage of zeolite-Y
as a new orange-red phosphor for the white light-emitting diode (WLED).
The composites have significantly improved resistance to both elevated
temperature and water over the bare Mn<sup>2+</sup>-doped QDs. The
former exhibits little degradation whereas the latter shows apparent
decline upon the irradiation of lights in the orange LED devices,
which are fabricated by employing each material as a color-conversion
phosphor coated on a 365 nm UV chip. A WLED is also achieved with
a 365 nm UV chip coated with a CsPbĀ(Cl<sub>0.5</sub>,Br<sub>0.5</sub>)<sub>3</sub>āY blue phosphor and a CsPb<sub>0.75</sub>Mn<sub>0.25</sub>Cl<sub>3</sub>āY orange phosphor. The device possesses
a Commission Internationale de lāEĢclairage coordinate
of (0.34, 0.36), a correlated color temperature of 5336 K and a color
rendering index of 81