Lu C.-H.Yang C.-Y.Som S.Das S.2019-05-132019-05-13201800027820https://scholars.lib.ntu.edu.tw/handle/123456789/407334A modified chemical vapor deposition (CVD) technique is used to synthesize the color-tunable siliconitride Sr2-1.5x-yCexEuySi5N8 (x?=?0.000-0.016 and y?=?0.000-0.020) phosphors. In comparison with the conventional solid-state method, the CVD approach successfully improved the crystallinity, particle size distribution, and photoluminescence through the enhanced gas-solid reaction. Under blue excitation, Sr1.98Eu0.02Si5N8 exhibited a red emission band at 618?nm. The incorporation of Ce3+ ions increased the emission intensity of Eu2+ ions by approximately 10% owing to the enhanced absorption and dipole-dipole energy transfer process from Ce3+ to Eu2+ ions. It resulted in a shift of the emission colors from yellow to red region. The external and internal quantum efficiencies of Sr1.906Ce0.06Eu0.004Si5N8 were calculated as 54% and 70%, respectively. The activation energy of thermal stability for Sr1.906Ce0.06Eu0.004Si5N8 was evaluated as 0.31?eV. A white LED with a color rendering index of 80 and a CCT of 4964?K was successfully fabricated with the present phosphors. The current research demonstrated a new series of Sr2Si5N8:Ce3+, Eu2+ phosphors with color-tunability for fabricating white LEDs with high color-rendering index. ? 2018 The American Ceramic Societychemical vapor depositionspectroscopic characterizationwhite light-emitting diodejournal article10.1111/jace.159142-s2.0-85050655586https://www.scopus.com/inward/record.uri?eid=2-s2.0-85050655586&doi=10.1111%2fjace.15914&partnerID=40&md5=284cf148c52e3c858db10ae5b124f81e