A tunable blue–cyan dual emission phosphor in Ca_4−xLu_2xHf_1−xGe₃O₁₂:Bi³⁺ via forming segregation structure for WLEDs

Abstract: White light-emitting diodes (WLEDs) are always fabricated by a combination of the near-ultraviolet (n-UV)-emitting LED chip with tricolor emitting phosphors.However, improving the color rendering index (CRI) is limited due to the absence of cyan composition for common commercial combinations. Based on this, a series of blue-cyan dual-peaks emission Ca 4−x Lu 2x Hf 1−x Ge 3 O 12 (CLHGO):Bi 3+ phosphors with unique adjustability are developed by the solid solution design strategy. All the samples belong to the g… Show more

“…[15][16][17] However, the cyan gap at 470-520 nm reduces the CRI value and limits the obtainment of full-spectrum lighting in devices combining commercial red, green, and blue phosphors with violet chips. [18][19][20][21] Therefore, to obtain fullspectrum illumination, there is an urgent need to explore high-performance violet light-excited cyan fluorescent materials.…”

“…Therefore, as an alternative to overcome the drawbacks mentioned above, the combination of violet (380–420 nm) chips with multicolor phosphors to obtain full‐spectrum illumination has been proposed 15–17 . However, the cyan gap at 470–520 nm reduces the CRI value and limits the obtainment of full‐spectrum lighting in devices combining commercial red, green, and blue phosphors with violet chips 18–21 . Therefore, to obtain full‐spectrum illumination, there is an urgent need to explore high‐performance violet light‐excited cyan fluorescent materials.…”

Overcoming the cyan gap for full‐spectrum lighting using cation‐substitution‐induced rigid Ca₂YZr₂Al₃O₁₂:Ce³⁺

“…[15][16][17] However, the cyan gap at 470-520 nm reduces the CRI value and limits the obtainment of full-spectrum lighting in devices combining commercial red, green, and blue phosphors with violet chips. [18][19][20][21] Therefore, to obtain fullspectrum illumination, there is an urgent need to explore high-performance violet light-excited cyan fluorescent materials.…”

“…Therefore, as an alternative to overcome the drawbacks mentioned above, the combination of violet (380–420 nm) chips with multicolor phosphors to obtain full‐spectrum illumination has been proposed 15–17 . However, the cyan gap at 470–520 nm reduces the CRI value and limits the obtainment of full‐spectrum lighting in devices combining commercial red, green, and blue phosphors with violet chips 18–21 . Therefore, to obtain full‐spectrum illumination, there is an urgent need to explore high‐performance violet light‐excited cyan fluorescent materials.…”

Overcoming the cyan gap for full‐spectrum lighting using cation‐substitution‐induced rigid Ca₂YZr₂Al₃O₁₂:Ce³⁺

Luminescent properties of Y2LaCaGa3ZrO12: Bi3+, Al3+ cyan phosphors for application in white light emitting diodes

Regulating the redshift of the charge transfer band edge and antithermal quenching by ion substitution strategy in YP1-xVxO4:Eu3+ phosphor