Abstract
Color rendition, luminous efficacy and reliability are three key technical parameters for white light-emitting diodes (wLEDs) that are dominantly determined by down-conversion phosphors. However, there is usually an inevitable trade-off between color rendition and luminescence efficacy because the spectrum of red phosphor (that is, spectral broadness and position) cannot satisfy them simultaneously. In this work, we report a very promising red phosphor that can minimize the aforementioned trade-off via structure and band-gap engineering, achieved by introducing isostructural LiSi2N3 into CaAlSiN3:Eu2+. The solid solution phosphors show both substantial spectra broadening (88→117 nm) and blueshift (652→642 nm), along with a significant improvement in thermal quenching (only a 6% reduction at 150 °C), which are strongly associated with electronic and crystal structure evolutions. The broadband and robust red phosphor thus enables fabrication of super-high color rendering wLEDs (Ra=95 and R9=96) concurrently with the maintenance of a high-luminous efficacy (101 lm W−1), validating its superiority in high-performance solid state lightings over currently used red phosphors.
Highlights
IntroductionWhite light-emitting diodes (wLEDs) are broadly known as one of most efficient and environmental friendly lighting technology, greatly contributing to energy saving and greenhouse gas reduction[1,2]
White light-emitting diodes are broadly known as one of most efficient and environmental friendly lighting technology, greatly contributing to energy saving and greenhouse gas reduction[1,2]. They are gradually replacing traditional incandescent bulbs and fluorescence tubes for general lighting, and their luminous efficacy, color rendition and reliability are key factors determining these replacements. For those wLEDs using a single garnet yellow phosphor (Y3Al5O12:Ce3+), the insufficient red component in the spectra leads to a small color rendering index (Rao80), making them unsuitable for high-quality general lighting[3]
We demonstrate that by using the Ca1 − xLixAl1 − xSi1+xN3:Eu2+ (x = 0.20) red phosphor, a super-high color rendering index (Ra = 95 and R9 = 96) can be achieved without compromising the luminous efficacy (~101 lm W − 1) of wLEDs
Summary
White light-emitting diodes (wLEDs) are broadly known as one of most efficient and environmental friendly lighting technology, greatly contributing to energy saving and greenhouse gas reduction[1,2] They are gradually replacing traditional incandescent bulbs and fluorescence tubes for general lighting, and their luminous efficacy, color rendition and reliability are key factors determining these replacements. For those wLEDs using a single garnet yellow phosphor (Y3Al5O12:Ce3+), the insufficient red component in the spectra leads to a small color rendering index (Rao80), making them unsuitable for high-quality general lighting[3]. Several promising red-emitting phosphors have been proven to effectively enhance the color rendition, including (Ca, Sr, Ba)2Si5N8:Eu2+ (ref. 9), (Sr, Ca)AlSiN3:Eu2+ (refs 10,11), SrLiAl3N4:Eu2+ (ref. 12) and K2(Si, Ti)F6:Mn4+ (refs 8,13)
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