Tunable Multicolor Phosphorescence of Crystalline Polymeric Complex Salts with Metallophilic Backbones

Liu, Qi; Xie, Mo; Chang, Xiaoyong; Cao, Shuang; Zou, Chao; Fu, Wen‐Fu; Che, Chi‐Ming; Chen, Yong; Lu, Wei

doi:10.1002/ange.201803965

Cited by 25 publications

(8 citation statements)

References 43 publications

(31 reference statements)

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“…The emission of PtD-g shows characteristic vibronic structures of ligand-centered 3 π−π* ( 3 IL) transition, while that of PtD-y is structureless. These emissions are attributed to an admixture of 3 MLCT and 3 IL transitions, 32 which is also supported by TDDFT calculations (Figure S9).…”

supporting

confidence: 68%

Photoluminescent Anisotropy Amplification in Polymorphic Organic Nanocrystals by Light-Harvesting Energy Transfer

et al. 2019

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Polymorphism and anisotropy are fundamental phenomena of crystalline materials. However, the structure-dependent photoluminescent (PL) anisotropy in polymorphic organic crystals has remained unexplored. Herein, two polymorphic nanocrystals, green-emitting nanorods (PtD-g) and yellow-emitting nanoplates (PtD-y), were obtained from a platinum(II)−β-diketonate complex. The PtD-y crystals display remarkable PL anisotropy with an anisotropy ratio of up to 0.87 whereas the emission of the PtD-g crystals is nearly unpolarized. The polarization properties are rationalized on the different molecular packing of these crystals. By light-harvesting energy transfer, the PtD-y crystals are successfully used to amplify the emission polarization of a red-emitting platinum acceptor (PtA) doped into the donor crystalline matrix, which is otherwise weakly polarized as pure crystals.

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confidence: 68%

Photoluminescent Anisotropy Amplification in Polymorphic Organic Nanocrystals by Light-Harvesting Energy Transfer

et al. 2019

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“…However, most recent studies have focused on the consequences of variations of Au•••Au interactions rather than Au−S bond lengths on luminescence. 22,23 Au(I) sulfur complexes usually adopt Au n S (n = 1−6) coordination modes, 24,25 and complexes with Au−S 26,27 or Au 2 −μ-S bonds 28 tend to exhibit enhanced luminescence because of shorter Au−S bonds (∼2. 35 Å).…”

Section: ■ Introductionmentioning

confidence: 99%

Fine-Tuning of Luminescence through Changes in Au–S Bond Lengths as a Function of Temperature or Solvent

et al. 2019

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The luminescent properties of gold(I)–sulfur compounds have received much attention for their potential applications in the sensing field. The molecular level regulation of luminescence remains a challenge. It is critical to unravel the relationship between the luminescence and the structure. Herein we report a binuclear complex [Au2(dppaptc)2]Cl2 (1, dppaptc = N,N-bis(diphenylphosphanylmethyl)-amino-4-phenyl-thiocarbamide), which exhibits variations at Au–S bond lengths as a function of temperature or solvent. X-ray analysis reveals a linear decrease from 2.900(3) to 2.745(15) Å upon cooling 1·2CHCl3 from 300 to 80 K combined with a linear correlation with its luminescence intensity at 475 nm, which was confirmed by TD-DFT calculations. Compound 1, if solvated with H2O and alcohol, possesses the shorter Au–S bonds and enhanced luminescence. The close relationship between luminescence intensity and Au–S length serves as a complement to existing luminescent gold(I)–sulfur systems and provides some insight into understanding the thermochromism and solvatochromism of the gold(I)–sulfur compounds.

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“…These results recently promptedu st os tudy the electronic and photophysical properties resulting from the introduction of as econd nitrogen atom. In the literaturei midazopyrazine complexes of gold(I), [20] silver(I), [21] rhodium(I), [21] copper(I), [22] and platinum(II) [23] are known. We compared the electronic and spectroscopic properties of the imidazopyrazine complex with those observed for related systems ( Figure 2, complexes 1-3).…”

Section: Introductionmentioning

confidence: 99%

Sky‐Blue Triplet Emitters with Cyclometalated Imidazopyrazine‐Based NHC‐Ligands and Aromatic Bulky Acetylacetonates

Pinter

Soellner

Straßner

2019

Chemistry A European J

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Platinum(II) complexes with an N‐heterocyclic carbene and a cyclometalating phenyl ligand (C^C*) are excellent candidates as efficient blue triplet emitters for OLED applications. The electronic and photophysical properties of these complexes can be fine‐tuned with the objective to increase the quantum yields and lower the phosphorescence decay times. We found that platinum complexes with an imidazopyrazine C^C* ligand and bulky acetylacetonates are sky‐blue triplet emitters, characterised by an almost unitary quantum yield and short phosphorescence decay times.

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Tunable Multicolor Phosphorescence of Crystalline Polymeric Complex Salts with Metallophilic Backbones

Cited by 25 publications

References 43 publications

Photoluminescent Anisotropy Amplification in Polymorphic Organic Nanocrystals by Light-Harvesting Energy Transfer

Photoluminescent Anisotropy Amplification in Polymorphic Organic Nanocrystals by Light-Harvesting Energy Transfer

Fine-Tuning of Luminescence through Changes in Au–S Bond Lengths as a Function of Temperature or Solvent

Sky‐Blue Triplet Emitters with Cyclometalated Imidazopyrazine‐Based NHC‐Ligands and Aromatic Bulky Acetylacetonates

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