Bright cyan emission from Eu-Doped borosilicate glasses by optimizing reduction of Eu3+ to Eu2+ in ambient atmosphere

Abstract

Although substantial strides have been made in exploring the blue and red emissions of amorphous glass under near-ultraviolet excitation for LEDs purpose, the lack of the cyan emission heavily hinders the full spectra LED towards high-quality application. Addressing this cyan gap in white-light LED technology calls for the doping of Eu2+ as the doping center for its highly efficient luminescence. However, Eu3+ as an oxidation state of europium ions poses a critical challenge in effectively reducing to its reduction state. A popular method for reduction involves using mixed gases such as N2/H2 or CO gases in a reaction container, yet this approach brings about environmental pollution and increases production costs. In this work, we proposed a novel strategy that bright cyan emission can be achieved in Eu-doped borosilicate glasses by optimizing reduction of Eu3+ to Eu2+ in ambient atmosphere. It is observed a gradual increase in the band emission intensity associated with the reduced Eu2+, accompanied with a concurrent decrease in the sharp peak intensity linked with Eu3+ with the growing Si3N4 content. The effect of both melting temperature and synthesis time on reduction effect on the reduction of Eu3+ to Eu2+ ions were also investigated. It is revealed that either longer synthesis times or higher melting temperatures diminished the efficient reduction of Eu3+ to Eu2+ ions during the first-melting. Expanding on the Si3N4 reduction method, we employed an external bamboo charcoal approach to produce Eu-doped borosilicate glass under various synthesis times during the secondary melting. The results show that longer synthesis times attributed to the reduction effect. Finally, the optimized cyan-emitting glass sample is featured with emission wavelength of 486 nm, a transmittance of 84 %, and a quantum yield of 37.97 %. All the significant results are paving the solid way to prepare cyan-emitting glasses in the future.