Tuning Emission Wavelength of Polymorphous Crystal via Controllable Alkyl Chain Stacking and Its Vapor‐ and Thermo‐Responsive Fluorescence

Peng, Lu; Wei, Ruixue; Guo, Yao; Zheng, Xiaokun; Zheng, Yue; Ding, Yiwen; Yu, Xiaojun; Tong, Aijun

doi:10.1002/chem.201900722

Cited by 6 publications

(2 citation statements)

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“…[193] In addition, different polymorphs of the same ESIPT-based AIEgen can also be converted by griding, melting, vapor, annealing, and so on. [178,179,214] As a result, the ESIPT-based AIEgens will change the color and can be applied as stimuli-responsive materials.…”

Section: Other Applicationsmentioning

confidence: 99%

ESIPT‐based AIE luminogens: Design strategies, applications, and mechanisms

2022

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In this review, we present a systematic and comprehensive summary of the recent development and applications of excited-state intramolecular proton transfer-based (ESIPT-based) aggregation-induced emission luminogens (AIEgens), a type of promising materials that inherit the advantages of ESIPT and AIE, such as large Stokes shift, excellent photostability, and low self-quenching. We first summarize the backbones that have been used to construct the ESIPT-based AIEgens and classify the constructed ones based on the relation between ESIPT and AIE unit. According to the sensing mechanisms and design strategies, we have reviewed the applications of ESIPT-based AIEgens in bioimaging, drug delivery systems, organic lightemitting diodes, photo-patterning, liquid crystal, and the detection of metal cations, anions, small molecules, biothiols, biological enzymes, latent fingerprinting, and so on. We have also reviewed the recent advances in the development of new theoretical methods for investigating molecular photochemistry in crystals and their applications in ESIPT-based AIEgens. We discussed the remaining challenges in this field and the issues that need to be addressed. We anticipate that this review can provide a comprehensive picture of the current condition of research in this field, and promote researchers to make more efforts to develop novel ESIPT-based AIEgens with new applications.

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Section: Other Applicationsmentioning

confidence: 99%

ESIPT‐based AIE luminogens: Design strategies, applications, and mechanisms

2022

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“…The design and study of organic molecules exhibiting excited-state intramolecular proton transfer (ESIPT) properties have recently gained much momentum, notably because such fluorophores have a wide variety of potential applications. − Typically, ESIPT is a four-level photochemical cycle (E → E* → K* → K) involving photoexcitation of a molecule in the ground enol-state (E) to an excited enol*-state (E*), followed by fast tautomerization ( k ESIPT ≈ 10 12 s –1 ), leading to the excited keto*-state (K*), which then decays radiatively to its ground keto-state (K). − This usually results in large Stokes shifts and dual emission when the radiative decay occurs from both E* and K* states. − In the past few years, important efforts have been made to merge ESIPT properties with useful photophysical phenomena. Hence, diverse molecular designs allowing the combination of ESIPT with thermally activated fluorescence, phosphorescence or long persistent luminescence, aggregation-induced emission, amplified spontaneous emission, as well as multiple stimuli-responsive emissions have been reported, leading to the potential in different fields including sensing, displaying, lasing, imaging, and so forth. − …”

Section: Introductionmentioning

confidence: 99%

Interplay of Dual-Proton Transfer Relay to Achieve Full-Color Panel Luminescence in Excited-State Intramolecular Proton Transfer (ESIPT) Fluorophores

et al. 2023

ACS Appl. Mater. Interfaces

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A new design was applied for the facile synthesis of pure organic photoluminescent molecules with dual excited-state intramolecular proton transfer (ESIPT) sites. In this novel class of emitters, full-color panel emission from blue, green, and yellow to red, including white light, can be achieved in different solvents as modulated by the enol−keto(1st)−keto(2nd) tautomer emissions. A comprehensive transient photophysical study verifies that keto(1st) and keto(2nd) have a precursor (<0.8 ps)− successor (∼20 ps)-relayed absorbance relationship, and then a fast equilibrium between the two is established, resulting in dual emissions in the nanosecond scale (∼1900 ps). Through the research on copper ions' selective PL response, the dual-ESIPT mechanism was further verified; in addition, the study of solid-state PL changes upon the stimulus of organic vapor manifests the potential application sensitivity of the molecules as dual-ESIPT sensors. Theoretical results including reaction potential energy surface analyses manifest the fact that dual-proton transfer goes along a sequential route with a smaller energy barrier, firmly supporting the experimental results. An intrinsic system that undergoes intramolecular double proton relayed transfer is thus established for the achievement of much broadened optical responses and full-color display, providing reference for the design and application of advanced dual-ESIPT optical materials.

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Typical AIEgens Design

Zheng

Tong

2022

Handbook of Aggregation‐Induced Emission

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Tuning Emission Wavelength of Polymorphous Crystal via Controllable Alkyl Chain Stacking and Its Vapor‐ and Thermo‐Responsive Fluorescence

Cited by 6 publications

References 61 publications

ESIPT‐based AIE luminogens: Design strategies, applications, and mechanisms

ESIPT‐based AIE luminogens: Design strategies, applications, and mechanisms

Interplay of Dual-Proton Transfer Relay to Achieve Full-Color Panel Luminescence in Excited-State Intramolecular Proton Transfer (ESIPT) Fluorophores

Typical AIEgens Design

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