Toward an energy-efficient synthesis method to improve persistent luminescence of Sr2MgSi2O7:Eu2+,Dy3+ materials
Tipo
Artigo
Data de publicação
2021
Periódico
Materialia
Citações (Scopus)
11
Autores
Merizio L.G.
Bonturim E.
Ichikawa R.U.
Silva I.G.N.
Teixeira V.C.
Rodrigues L.C.V.
Brito H.F.
Bonturim E.
Ichikawa R.U.
Silva I.G.N.
Teixeira V.C.
Rodrigues L.C.V.
Brito H.F.
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© 2021The synthesis of persistent luminescent materials usually requires a multi-step long time annealing at high temperatures (>1200°C) in a resistive oven, causing a huge energy consumption. Also, to achieve reduced oxidation states of emitter ions (e.g., Eu3+ → Eu2+ ), the H2(g) atmosphere is often used, which can be dangerous and increase the costs of the process. Therefore, the development of a quick and new single-step green strategy, using in-situ low-risk atmosphere (e.g., CO(g)) and a microwave-assisted solid-state (MASS) method has been encouraged. In this work, we present a single-step method to synthesize the compound Sr2MgSi2O7:Eu2+,Dy3+ using the MASS method and the results were compared with those prepared by a conventional ceramic method. The luminescent material was prepared in 25 min of synthesis using carbon as a microwave susceptor and CO(g) atmosphere source at the same time. A higher concentration of Eu2+ emitter was identified by XANES in the MASS method product, which has a significant effect on the luminescence efficiency, as well as an improvement in the optical properties, leading to an emission 100 times more intense. Furthermore, to understand the Eu3+ reduction process under CO(g) atmosphere, we present here the innovative results of in-situ XANES analysis for the Sr2MgSi2O7:Eu2+,Dy3+ material. Finally, the MASS method makes it possible to prepare the materials with less than 5% of the ceramic method's duration in time. The energy-saving and better-quality persistent luminescent properties obtained in the MASS method provide viable applications on anti-counterfeiting markers, solar cell sensitizers, and other luminescent technologies.
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Assuntos Scopus
Ceramic methods , Efficient synthesis , Energy efficient , Luminescent material , Microwave-assisted , Microwave-assisted solid-state synthesis , Rare-earths , Solid state method , Solid-state reactions , Solid-state synthesis