Chiral iridium(<scp>iii</scp>) complexes with four-membered Ir–S–P–S chelating rings for high-performance circularly polarized OLEDs

Yan, Zhi‐Ping; Liao, Kang; Han, Hua‐Bo; Su, Jian; Zheng, You‐Xuan; Zuo, Jing‐Lin

doi:10.1039/c9cc03915e

Cited by 93 publications

(47 citation statements)

References 30 publications

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“…(A) Homoleptic fac -[Ir(pppy) 3 ] complex (Schaffner-Hamann et al, 2004 ). Heteroleptic complexes [Ir(C ∧ N) 2 (X ∧ Y)] n+ holding (B) achiral C ∧ N and chiral X ∧ Y ligands (Li et al, 2016 ; Mazzeo et al, 2016 ; Li L.-P. et al, 2017 ; Manguin et al, 2019 ; Yan et al, 2019a ), (C) chiral C ∧ N and achiral X ∧ Y ligands (Yang et al, 2009 ), (D) chiral C ∧ N and X ∧ Y ligands (Yan et al, 2018 ), and (E) helicenic–NHC chiral ligand X ∧ Y (Hellou et al, 2017 ; Macé et al, 2019 ).…”

Section: Second- and Third-row Transition Metal Complexes For Cplmentioning

confidence: 99%

“…Apart from 13 , the chemical attention usually focused on heteroleptic [Ir(C ∧ N) 2 (X ∧ Y)] n+ complexes probably because they are obtained by the simple reaction of the aforementioned Ir III intermediates ([Ir(C ∧ N) 2 Cl 2 ] − or [(Ir(C ∧ N) 2 Cl) 2 ]) with enantiopure ligands, a versatile strategy which produces a library of complexes with various chiral ligands. In particular, the combination of achiral C ∧ N ligands with a chiral X ∧ Y one afforded the most important library of [Ir(C ∧ N) 2 (X ∧ Y)] n+ complexes for CPL, mainly based on central chirality ( 14 – 17 ) (Li et al, 2016 ; Mazzeo et al, 2016 ; Li L.-P. et al, 2017 ; Manguin et al, 2019 ), albeit axial chirality was occasionally exploited with ligands containing 1,1′-bi-2-naphthol derivatives ( 18 – 19 ) ( Figure 8B ) (Han et al, 2017b ; Yan et al, 2019a ). Although a few examples report on full chiral induction ( 14 ) (Li L.-P. et al, 2017 ), in most cases the separation of the formed diastereoisomer pair was achieved by selective diasteroisomer precipitation ( 15 ) (Mazzeo et al, 2016 ), by HPLC ( 16 ) (Li et al, 2016 ), or by silica column chromatography ( 17 – 19 ) (Manguin et al, 2019 ; Yan et al, 2019a ).…”

Section: Second- and Third-row Transition Metal Complexes For Cplmentioning

confidence: 99%

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Beyond Chiral Organic (p-Block) Chromophores for Circularly Polarized Luminescence: The Success of d-Block and f-Block Chiral Complexes

2020

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Chiral molecules are essential for the development of advanced technological applications in spintronic and photonic. The best systems should produce large circularly polarized luminescence (CPL) as estimated by their dissymmetry factor ( g lum ), which can reach the maximum values of −2 ≤ g lum ≤ 2 when either pure right- or left-handed polarized light is emitted after standard excitation. For matching this requirement, theoretical considerations indicate that optical transitions with large magnetic and weak electric transition dipole moments represent the holy grail of CPL. Because of their detrimental strong and allowed electric dipole transitions, popular chiral emissive organic molecules display generally moderate dissymmetry factors (10 −5 ≤ g lum ≤ 10 −3 ). However, recent efforts in this field show that g lum can be significantly enhanced when the chiral organic activators are part of chiral supramolecular assemblies or of liquid crystalline materials. At the other extreme, chiral Eu III - and Sm III -based complexes, which possess intra-shell parity-forbidden electric but allowed magnetic dipole transitions, have yielded the largest dissymmetry factor reported so far with g lum ~ 1.38. Consequently, 4f-based metal complexes with strong CPL are currently the best candidates for potential technological applications. They however suffer from the need for highly pure samples and from considerable production costs. In this context, chiral earth-abundant and cheap d-block metal complexes benefit from a renewed interest according that their CPL signal can be optimized despite the larger covalency displayed by d-block cations compared with 4f-block analogs. This essay thus aims at providing a minimum overview of the theoretical aspects rationalizing circularly polarized luminescence and their exploitation for the design of chiral emissive metal complexes with strong CPL. Beyond the corroboration that f–f transitions are ideal candidates for generating large dissymmetry factors, a special attention is focused on the recent attempts to use chiral Cr III -based complexes that reach values of g lum up to 0.2. This could pave the way for replacing high-cost rare earths with cheap transition metals for CPL applications.

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Section: Second- and Third-row Transition Metal Complexes For Cplmentioning

confidence: 99%

Section: Second- and Third-row Transition Metal Complexes For Cplmentioning

confidence: 99%

Beyond Chiral Organic (p-Block) Chromophores for Circularly Polarized Luminescence: The Success of d-Block and f-Block Chiral Complexes

2020

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“…fluorescence materials (Feuillastre et al, 2016;Han et al, 2017;Wu et al, 2019) exhibit increasingly satisfactory results in term of the electroluminescence properties. Nevertheless, most of these materials used in efficient OLEDs exhibit poor CPL properties with the |g PL | value in the range of 10 −5 to 10 −3 (Han et al, 2018;Yan et al, 2019b) and mostly <5 × 10 −3 . Hence, it is important to provide a design strategy to improve their CPL properties.…”

Section: Introductionmentioning

confidence: 99%

Rational Design of the Platinahelicene Enantiomers for Deep-Red Circularly Polarized Organic Light-Emitting Diodes

et al. 2020

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Helicene derivatives are most popular chiral structures to construct luminescent materials with circularly polarized (CP) light, which have revealed appealing application in chiral optoelectronics. Particularly, because of the unique phosphorescent emission, platinahelicene has great application prospects in CP organic light-emitting diode (CP-OLED). Herein, by decorating the pyridinyl-helicene ligand with trifluoromethyl (-CF 3) unit in a specific position, a pair of platinahelicene enantiomers was prepared and separated with extremely twisted structure showing not only superior thermal and configurational stability but also good CP luminescence (CPL) property with dissymmetry factors (|g PL |) of 6 × 10 −3. Moreover, the evaporated CP-OLEDs based on platinahelicene enantiomers exhibited the deep-red emission with the peak at 653 nm as well as obvious CP electroluminescence (CPEL) signals with the |g EL | in 10 −3 order. Therefore, the design strategy provides an efficient way to improve the CPL properties of platinahelicene to cope with the future application in CP-OLEDs.

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“…Especially these phosphorescent transition metal complexes, which have remarkable metal-center chirality, tunable emission properties, and unusually high phosphorescence efficiency, are receiving increasing interests in recent years (Han et al, 2018). Such CPL-active materials as Pt (Shen et al, 2014), Ir (Han et al, 2017;Hellou et al, 2017;Yan et al, 2019a), Au (Yang et al, 2020;Zhu et al, 2020), Cu (Jin et al, 2019;Deng et al, 2020;Yao et al, 2020), Zn (Aoki et al, 2017;Chen Y. et al, 2019) Cd (Deng et al, 2019), and Cr (Jiménez et al, 2019) complexes can exhibit various emission colors from blue to red. The dissymmetry factor g lum (g lum = 2 I/I = 2(I L -I R )/(I L + I R ), where I L and I R indicate, respectively, the intensity of the left and right circularly polarized light), can reach up to 10 −2 order.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Circularly Polarized Luminescence Activity in Chiral Platinum(II) Complexes With Bis- or Triphenylphosphine Ligands

et al. 2020

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Distinct circularly polarized luminescence (CPL) activity was observed in chiral (C ∧ N ∧ N)Pt(II) [(C ∧ N ∧ N) = 4,5-pinene-6 ′-phenyl-2,2 ′-bipyridine] complexes with bis-or triphenylphosphine ligands. Compared to the pseudo-square-planar geometry of chiral (C ∧ N ∧ N)Pt(II) complexes with chloride, phenylacetylene (PPV) and 2,6-dimethylphenyl isocyanide (Dmpi) ligands, the coordination configuration around the Pt(II) nucleus of chiral (C ∧ N ∧ N)Pt(II) complexes with bulk phosphine ligands is far more distorted. The geometry is straightforwardly confirmed by X-ray crystallography. The phosphines' participation enhanced the CPL signal of Pt(II) complexes profoundly, with the dissymmetry factor (g lum) up to 10 −3. The distorted structures and enhanced chiroptical signals were further confirmed by time-dependent density functional theory (TD-DFT) calculations.

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Chiral iridium(iii) complexes with four-membered Ir–S–P–S chelating rings for high-performance circularly polarized OLEDs

Abstract: CP-OLEDs with two series of chiral iridium(iii) complexes based on four-membered Ir–S–P–S chelating rings and chiral BINOL-based derivatives show excellent electroluminescence performances with obvious CPEL properties.

Cited by 93 publications

References 30 publications

Beyond Chiral Organic (p-Block) Chromophores for Circularly Polarized Luminescence: The Success of d-Block and f-Block Chiral Complexes

Beyond Chiral Organic (p-Block) Chromophores for Circularly Polarized Luminescence: The Success of d-Block and f-Block Chiral Complexes

Rational Design of the Platinahelicene Enantiomers for Deep-Red Circularly Polarized Organic Light-Emitting Diodes

Enhanced Circularly Polarized Luminescence Activity in Chiral Platinum(II) Complexes With Bis- or Triphenylphosphine Ligands

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