Luminescence tuning and single-phase white light emitters based on rare earth ions doped into a bismuth coordination network.

Cunha, C. S., Köppen, M., Terraschke, H., Friedrichs, Gernot, Malta, O. L., Stock, N. and Brito, H. F. (2018) Luminescence tuning and single-phase white light emitters based on rare earth ions doped into a bismuth coordination network. Journal of Materials Chemistry C, 6 (46). pp. 12668-12678. DOI 10.1039/C8TC04442B.

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Abstract

The coordination network consisting of trivalent bismuth ions and pyromellitic acid (H4Pyr), [Bi(HPyr)], was successfully applied as a host matrix for in situ incorporation of trivalent rare earth (RE3+) ions Sm3+, Eu3+, Tb3+ and Dy3+. High-throughput methods for hydrothermal synthesis allowed us to prepare and study the phase purity and crystallinity of the sample series, accelerating and facilitating the comparison between the synthesis parameters. Infrared absorption spectroscopy, elemental and thermogravimetric analysis, scanning electron microscopy and energy-dispersive X-ray spectroscopy, as well as powder X-ray diffraction and refinement of the unit cell parameters of the compounds, indicated that doping did not affect the structure, crystallinity, morphology and thermal stability of the matrix. The study of the spectroscopic luminescence properties of the nondoped and doped [Bi(HPyr)] allowed investigation of the sensitization processes of dopant RE3+ ions. The characteristic spectroscopic properties of the Eu3+ ion were used to study the incorporation site and coordination environment of the dopant by calculation of the experimental intensity parameters Ωλ (λ: 2 and 4) and intrinsic quantum yield of the Eu3+ single-doped [Bi(HPyr)]. Straightforward emission color tuning by changing the relative concentrations of the dopant ions is possible and has been studied for the four systems double-doped with Tb3+:Eu3+, Tb3+:Sm3+, Dy3+:Eu3+ and Dy3+:Sm3+ ions. The Dy-containing systems show different shades of white emission and a wide range of correlated color temperatures (CCT), ranging from 2500 to 7500 K, hence being a promising candidate for the development of single-phase white light emitting devices.

Document Type: Article
Research affiliation: Kiel University > Kiel Marine Science
OceanRep > The Future Ocean - Cluster of Excellence
Kiel University
Refereed: Yes
Open Access Journal?: No
DOI etc.: 10.1039/C8TC04442B
ISSN: 2050-7526
Projects: Future Ocean
Date Deposited: 20 Dec 2018 11:53
Last Modified: 27 Mar 2019 09:05
URI: http://oceanrep.geomar.de/id/eprint/45075

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