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A trimeric tri-Tb3+ including antimonotungstate and its Eu3+/Tb3+/Dy3+/Gd3+-codoped species with luminescence properties.

Authors :
Xu, Xin
Lu, Changtong
Xie, Saisai
Chen, Lijuan
Zhao, Junwei
Source :
Dalton Transactions: An International Journal of Inorganic Chemistry; 9/21/2020, Vol. 49 Issue 35, p12401-12410, 10p
Publication Year :
2020

Abstract

A trimeric tri-Tb<superscript>3+</superscript>-including antimonotungstate (AMT) hybrid Na<subscript>17</subscript>{(WO<subscript>4</subscript>)[Tb(H<subscript>2</subscript>O)(Ac)(B-α-SbW<subscript>9</subscript>O<subscript>31</subscript>(OH)<subscript>2</subscript>)]<subscript>3</subscript>}·50H<subscript>2</subscript>O (Tb<subscript>3</subscript>W<subscript>28</subscript>) was successfully synthesized, in which the capped tetrahedral {WO<subscript>4</subscript>} group plays a significant template role in directing the aggregation of three [B-α-SbW<subscript>9</subscript>O<subscript>33</subscript>]<superscript>9−</superscript> fragments and three Tb<superscript>3+</superscript> ions. Eu<superscript>3+</superscript>/Tb<superscript>3+</superscript>/Dy<superscript>3+</superscript>/Gd<superscript>3+</superscript>-codoped AMT materials based on Tb<subscript>3</subscript>W<subscript>28</subscript> were firstly prepared and their luminescence properties were investigated. The red emitter Eu<superscript>3+</superscript>, yellow emitter Dy<superscript>3+</superscript>, and nonluminous Gd<superscript>3+</superscript> ions were codoped into Tb<subscript>3</subscript>W<subscript>28</subscript> to substitute Tb<superscript>3+</superscript> ions for investigating the energy transfer (ET) mechanism among Eu<superscript>3+</superscript>, Tb<superscript>3+</superscript>, and Dy<superscript>3+</superscript> ions. Upon the <superscript>6</superscript>H<subscript>15/2</subscript> → <superscript>4</superscript>I<subscript>13/2</subscript> excitation at 389 nm of the Dy<superscript>3+</superscript> ion, the ET<subscript>1</subscript> mechanism (Dy<superscript>3+</superscript> → Tb<superscript>3+</superscript>) was confirmed as a non-radiative dipole–dipole interaction. Under the <superscript>7</superscript>F<subscript>6</subscript> → <superscript>5</superscript>L<subscript>10</subscript> excitation at 370 nm of the Tb<superscript>3+</superscript> ion, the ET<subscript>2</subscript> mechanism (Tb<superscript>3+</superscript> → Eu<superscript>3+</superscript>) was identified as a non-radiative quadrupole–quadrupole interaction. Under excitation at 389 nm, the two-step successive Dy<superscript>3+</superscript> → Tb<superscript>3+</superscript> → Eu<superscript>3+</superscript> ET<subscript>3</subscript> process was proved in Dy<subscript>1.2</subscript>Tb<subscript>3z</subscript>Eu<subscript>0.03</subscript>Gd<subscript>1.77−3z</subscript>W<subscript>28</subscript>. Through changing the excitation wavelengths, the emission color of Dy<subscript>1.2</subscript>Tb<subscript>1.2</subscript>Eu<subscript>0.03</subscript>Gd<subscript>0.57</subscript>W<subscript>28</subscript> can vary from blue to yellow, in which a near-white-light emission case was observed upon excitation at 378 nm. This work not only provides a systematic ET mechanism study of hetero-Ln-codoped AMTs, but also offers some useful guidance for designing novel performance-oriented Ln-codoped polyoxometalate-based materials. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
14779226
Volume :
49
Issue :
35
Database :
Complementary Index
Journal :
Dalton Transactions: An International Journal of Inorganic Chemistry
Publication Type :
Academic Journal
Accession number :
145890130
Full Text :
https://doi.org/10.1039/d0dt01985b