Litcius/Paper detail

Enhanced Synchronously Emission Dissymmetry Factor and Quantum Efficiency of Circularly Polarized Phosphorescence from Point-Chiral Cyclometalated Platinum(II) Liquid Crystal

Bo Yang, Hai‐Liang Ni, Haifeng Wang, Yuhui Hu, Kaijun Luo, Wenhao Yu

2020The Journal of Physical Chemistry C53 citationsDOI

Abstract

Circularly polarized luminescence (CPL) derived from supramolecular self-assembly chirality has been a fascinating field of research due to its applications in photoactive devices and bioactive probes. Herein, we report a straightforward pathway for the construction of efficient chirality transfer and enhanced circularly polarized phosphorescence based on platinum(II) metallomesogens via liquid crystal self-organization. Overall, two chiral metallomesogens, the enantiomeric complexes of (S)-Pt-L1 and (R)-Pt-L1, were obtained based on the combination of the rodlike achiral phenylpyridine and point-chiral pyridinic acid derivatives. Experiments with polarizing optical microscopy (POM), differential scanning calorimetry (DSC), and variable-temperature X-ray diffraction show that there are two smectic phases during cooling and heating processes, namely the high temperature SmC* and low temperature SmC phases, and the SmCh* phase. Interestingly, the circular dichroism (CD) and circularly polarized luminescence (CPL) tests reveal that the chirality transfer from the molecule to liquid crystal self-organization does occur indeed in the high temperature SmC* and SmCh* phases. However, both the CD and CPL signals are silent in the low temperature SmC phase, even in the solution, suggesting that chirality transfer depends on the self-organization superstructure of the liquid crystal. Moreover, the dissymmetry factor (|glum| = 4.0 × 10–2) in the high temperature SmC* phase is 1–2 orders of magnitude higher than that of Pt(II) complexes previously reported. Also, the elevated photoluminescence quantum yield (ΦPL = 0.46) is obtained for the liquid crystal film, indicating that the enhanced CPL properties can be achieved through self-organization of mesomorphic organoplatinum molecules. Another interesting observation is made that the racemic mixture ((S)-Pt-L1 and (R)-Pt-L1) shows spontaneous chirality separation in the high temperature SmC1 phase.

Topics & Concepts

PhosphorescenceChirality (physics)Circular dichroismLiquid crystalLuminescenceCrystallographyMaterials scienceSupramolecular chiralityDifferential scanning calorimetryQuantum yieldSupramolecular chemistryPhotoluminescenceEnantiomerPhase (matter)PlatinumCrystal structureChemistryFluorescenceStereochemistryOpticsOrganic chemistryOptoelectronicsPhysicsChiral symmetry breakingQuantum mechanicsQuarkNambu–Jona-Lasinio modelCatalysisThermodynamicsSynthesis and Properties of Aromatic CompoundsLuminescence and Fluorescent MaterialsLiquid Crystal Research Advancements