β-diketonates are customary bidentate ligands in highly luminescent ternary europium complexes, such as Eu(β-diketonate)3(L)2, where L stands for a nonionic ligand. Usually, the syntheses of these complexes start by adding, to an europium salt such as EuCl3(H2O)6, three equivalents of β-diketonate ligands to form the complexes Eu(β-diketonate)3(H2O)2. The nonionic ligands are subsequently added to form the target complexes Eu(β-diketonate)3(L)2. However, the Eu(β-diketonate)3(H2O)2 intermediates are frequently both difficult and slow to purify by recrystallization, a step which usually takes a long time, varying from days to several weeks, depending on the chosen β-diketonate. In this article, we advance a novel synthetic technique which does not use Eu(β-diketonate)3(H2O)2 as an intermediate. Instead, we start by adding 4 equivalents of a monodentate nonionic ligand L straight to EuCl3(H2O)6 to form a new intermediate: EuCl3(L)4(H2O)n, with n being either 3 or 4. The advantage is that these intermediates can now be easily, quickly, and efficiently purified. The β-diketonates are then carefully added to this intermediate to form the target complexes Eu(β-diketonate)3(L)2. For the cases studied, the 20-day average elapsed time reduced to 10 days for the faster synthesis, together with an improvement in the overall yield from 42% to 69%.
We demonstrate in a general and comprehensive manner that a substantial enhancement of luminescence in europium complexes can be achieved by increasing ionic ligand diversity. The measured boosts in quantum efficiency ranged from 100% to 543%.
We
advance the concept that a single efficient antenna ligand substituted in or
added to an otherwise weakly luminescent europium complex is enough
to significantly boost its luminescence. Our results, on the basis
of photophysical measurements on 5 novel europium complexes and 15
known ones, point in the direction that ligand dissimilarity and ligand
diversity are all concepts that clearly play a fundamental role in
the luminescence of europium complexes. We show that it is important
that a symmetry breaker ligand exists in the complex to enhance ligand
dissimilarity and ligand diversity, all mainly affecting the nonradiative
decay rate by reducing it. Because the presence of at least one antenna
ligand is also obviously necessary, the optimal and the most cost-effective
situation can be achieved by adding a single coordination symmetry
breaker that is also an efficient antenna, such as 1-(2-thenoyl)-3,3,3-trifluoroacetone
or 4,4,4-trifluoro-1-phenyl-1,3-butanedione. In such cases the quantum
efficiency, η, is decidedly boosted, as can be verified by going
from complex [EuCl
2
(TPPO)
4
]Cl·3H
2
O with η = 0% to the novel complex [EuCl
2
(BTFA)(TPPO)
3
], where TPPO stands for triphenylphosphine oxide, with η
= 62%.
Faced with many different plausible synthetic pathways for the preparation of europium complexes, the synthetic chemist can now easily compute RM1 thermodynamic quantities for all of them and likely arrive at the most effective synthetic strategies.
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