Litcius/Paper detail

Molecular and Aggregate Synergistic Engineering of Aggregation-Induced Emission Luminogens to Manipulate Optical/Electronic Properties for Efficient and Diversified Functions

Zheng Zheng, Tianyu Yang, Dongyu Li, Hui Cao, Junyi Gong, Haixiang Liu, Chengcheng Zhou, Lijie Liu, Peifa Wei, Xinggui Gu, Ping Lü, Jun Qian, Ben Zhong Tang

2023ACS Nano29 citationsDOI

Abstract

The optical/electronic properties of organic luminescent materials can be regulated by molecular structure modification, which not only requires sophisticated and time-consuming synthesis but also is unable to accurately afford the optical properties of materials in the aggregate state. Herein, a facile strategy of molecular and aggregate synergistic engineering is proposed to manipulate the optical/electronic properties of a luminogen, ACIK, in the solid state for efficient and diversified functions. ACIK is facilely synthesized and exhibits three polymorphic states (ACIK-Y, ACIK-R, and ACIK-N) with a large emission difference of 102 nm from yellow to near-infrared (NIR). Their structure–property relationships were investigated by crystallographic analyses and computational studies. ACIK-Y, with the most twisted structure, exhibits an intriguing color-tuned fluorescence between yellow and NIR in the solid state in response to multiple stimuli. Shuttle-like ACIK-R microcrystals exhibit an optical waveguide property with a low optical loss coefficient of 19 dB mm –1 . ACIK dots display bright NIR-I emission, large Stokes shift, and strong NIR-II two-photon absorption. ACIK dots show specific lipid droplets-targeting capability and can be successfully applied for two-photon fluorescence imaging of mouse brain vasculature with deep penetration and high spatial resolution. This study will inspire more insights in developing advanced optical/electronic materials based on a single chromophore for practical applications.

Topics & Concepts

ChromophoreMaterials scienceFluorescenceLuminescenceAbsorption (acoustics)Quantum dotAggregation-induced emissionOptoelectronicsChemical physicsNanotechnologyPhotochemistryChemistryOpticsPhysicsComposite materialLuminescence and Fluorescent MaterialsNanoplatforms for cancer theranosticsMolecular Sensors and Ion Detection