High efficient and ultrahigh thermal stability in a rigid rare-earth hybrid molecular crystal: [(CH3CH2)4N]Tb[CH2(SO3)2

Abstract

Organic-inorganic hybrid molecular fluorescent materials have attracted much attention due to their application potential in white LEDs and high-definition displays. However, achieving high thermal stability for the fields of lighting/displays remains greatly challenging based on the hybrid molecular materials. Herein, we reported a crystalline state 1D rigid rare-earth hybrid coordinate polymer molecular crystal [(CH3CH2)4N]Tb[CH2(SO3)2] (1) along with high quantum yield (QY) 75.2%. Interestingly, this hybrid molecular crystal remains stable up to 728 K (∼455 °C). Remarkably, it exhibits excellent fluorescence thermal stability at high temperatures (150 °C, >95% and 150–200 °C, >82%) and a high thermal activation energy of 568.7 meV. Besides, the fabricated n-UV chips based white-LED by 1, commercial red Y2O3:Eu3+ and blue BaMgAl10O17:Eu2+ phosphor emits white light with color coordinates (CIE, 0.33, 0.32), high color rendering index (CRI) of 91.2, and correlated color temperature (CCT) 5623 K. These results reveal that this ultrahigh thermal stability hybrid molecular crystal as a green phosphor has great potential applications for displays or WLEDs. Therefore, this study opens a new avenue to develop novel rare-earth phosphors and gives new visions for hybrid molecular fluorescent materials.