Wide‐Range Color‐Tunable Organic Phosphorescence Materials for Printable and Writable Security Inks

Lei, Yunxiang; Dai, Wenbo; Guan, Jianxin; Guo, Shuai; Ren, Fei; Zhou, Yiqing; Shi, Jianbing; Tong, Bin; Cai, Zhengxu; Zheng, Junrong; Dong, Yuping

doi:10.1002/anie.202003585

Cited by 372 publications

(314 citation statements)

References 59 publications

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“…Recently, our works have shown that the host molecule not only provides a rigid environment to restrict movement, but also contributes to the energy transfer of the guest molecule (Scheme 1). [7c, d] Herein, a new doped system with strong RTP property was developed through prediction and design, in which isoquinoline derivatives (IQL‐C n ) containing different alkoxy chains were selected as the guest molecules and cheap benzophenone (BPO) as the host molecule (Scheme 1). The guests were prepared from a simple three‐step procedure by using commercially available 2,6‐dimethyl‐4 H ‐pyran‐4‐one as the starting material according to Scheme S1 (in the Supporting Information) [8] .…”

Section: Methodsmentioning

confidence: 99%

“…To the best of our knowledge, this is the first time the effect of different alkoxy chains on the RTP properties of the doped materials has been studied. Based on the previously reported mechanism, [7c, d] BPO was chosen as the host owing to the characteristics of low melting point, good crystallinity, and phosphorescent emission. The low melting point facilitates the preparation of large quantities of the doped materials by the melt‐casting method, and the good crystallinity is conducive to providing a rigid environment for the guest molecules.…”

Section: Methodsmentioning

confidence: 99%

“…BPO is a typical phosphor with a maximum phosphorescence wavelength of 485 nm at room temperature, which is between the fluorescence wavelengths (around 440 nm) and phosphorescence wavelengths (around 550 nm) of the guests [9] . This means that the T 1 energy level of the host is between the T 1 and S 1 energy levels of the guests (Figure S9 in the Supporting Information), which is beneficial for the host to assist the energy transfer of the guests from the singlet state to the triplet state [7c, d] . Additionally, the melting point of BPO is only 48.5 °C (Figure S10 in the Supporting Information), so the guests can be uniformly dispersed in BPO by a simple melt‐casting method.…”

Section: Methodsmentioning

confidence: 99%

“…The interaction between host and guest molecules is an important factor for the RTP characteristic of the doped materials, and the reasonable contact between the host and guest molecules is the prerequisite for the intermolecular interactions [7a, c] . The longer alkoxy chain will hinder the reasonable contact between the guest molecule and the surrounding host molecules, which is not conducive to the host molecule assisting the energy transfer of the guest molecules.…”

Section: Methodsmentioning

confidence: 99%

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Tunable Phosphorescence/Fluorescence Dual Emissions of Organic Isoquinoline‐Benzophenone Doped Systems by Alkoxy Engineering

Chen

Xie

Shen

et al. 2020

Chemistry A European J

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Dual/multi-componento rganic doped systems with room-temperature phosphorescence (RTP) properties have been developed. However,t he unknown luminescence mechanism stillg reatly limits the development of the doped materials. Herein, an ew doped system exhibiting phosphorescence/fluorescence dual emission (F phos = 4-24 %a nd t phos = 101-343ms) is successfully constructed throughp rediction and design. As eries of isoquinoline derivatives with different alkoxyc hains were selecteda s the guests. Benzophenonew as chosena st he host owing to the characteristics of low melting point and good crystallinity. The alkoxy chain lengths of the guestsa re first reported to be used to control the fluorescence and phosphorescence intensitieso ft he doped materials,w hich results in different prompt emission colors. Additionally,t he doped ratio of the guest and host can also control the luminousi ntensitiesof the materials. In particular, the doped materialss till exhibit phosphorescent properties even if the ratio of the guest/host is as low as 1:100 000. Ultralong organic room-temperature phosphorescence (RTP) systemsw ith persistentl uminescence have great advantages in structured iversity,m ultiple functionality,a nd biocompatibility. [1] Therefore, RTP materials have attracted wide attention in the fields of anti-counterfeiting, optical recording, and biological imaging. [2] Generatinga sm any triplet excitons as possible and inhibiting the non-radiativet ransitions of excitons to the greatest extent are the key factorsf or the materials to exhibit Scheme1.Schematicdiagram of the host-guest-doped systems.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Tunable Phosphorescence/Fluorescence Dual Emissions of Organic Isoquinoline‐Benzophenone Doped Systems by Alkoxy Engineering

Chen

Xie

Shen

et al. 2020

Chemistry A European J

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“…Therefore, further development of versatile platforms to realize distinct p ‐RTP emissions from blue to red is highly desired. [ 21 ] On the other hand, most of these p ‐RTP materials just show a single emission color, and only scattered examples demonstrating excitation‐dependent [ 4 ] or time‐dependent emissions [ 22 ] were reported. If the afterglow color can vary with time, it would empower the materials with rich encryption modes in security protection, thus promoting more reliable protection at much higher levels.…”

Section: Figurementioning

confidence: 99%

Color‐Tunable, Excitation‐Dependent, and Time‐Dependent Afterglows from Pure Organic Amorphous Polymers

et al. 2020

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take the superiorities in processability, biocompatibility, rich source, wide variety, and low cost. [7] Generally, achieving pure organic p-RTP follows two criteria: i) promotion of intersystem crossing (ISC) through aggregation [8] and introduction of carbonyl, heteroatoms, and heavy atoms; [7] ii) suppression of the nonradiative relaxation processes (vibration or external quenchers). [7,9] Specifically, for the latter, various approaches, including crystal engineering, [10] host-guest doping or complexation, [11] H-aggregation, [2a,3b,12] construction of metal-organic framework and perovskite hybrids, [13,14] and ionic or ionic-π interactions, [15] were centrally developed. Currently explored systems, however, are predominantly molecular organic crystals, whose amorphous states show weakened or even disappeared p-RTP, [16] thus hampering their practical applications. To overcome these drawbacks, amorphous (p-) RTP systems were developed, which generally create rigid environment through powerful intermolecular interactions. [11a,b,17-20] Nevertheless, the color tunability in a wide-range remains a daunting challenge. Therefore, further development of versatile platforms to realize distinct p-RTP emissions from blue to red is highly desired. [21] On the other hand, most of these p-RTP materials just show a single emission color, and only scattered examples demonstrating excitation-dependent [4] or time-dependent emissions [22] were reported. If the afterglow color can vary with time, it would empower the materials with rich encryption modes in security protection, thus promoting more reliable protection at much higher levels. [22] For example, Chi et al. reported the first example with time-dependent afterglow colors through weak intermolecular hydrogen-bonding interaction. [22a] And very recently, Yang and coworkers reported similar phenomenon that originates from well-separated thermally activated delayed fluorescence (TADF) and p-RTP with comparable but different lifetimes. [22b] Meanwhile, as an alternative to molecular p-RTP compounds, polymers are even more attractive on account of their film-forming ability, which is favorable for diverse technical applications with flexibility and ease processing procedures. [23] However, the development of a simple approach to fabricate amorphous polymers with color-tunable and multicolor p-RTP in response to excitation wavelength (λ ex), particularly those also accompanying time-dependent afterglows, remains highly challenging. Here we report such system based on sodium Achieving persistent room-temperature phosphorescence (p-RTP), particularly those of tunable full-colors, from pure organic amorphous polymers is attractive but challenging. Particularly, those with tunable multicolor p-RTP in response to excitation wavelength and time are highly important but both fundamentally and technically underexplored. Here, a facile and general strategy toward color-tunable p-RTP from blue to orange-red based on amidation grafting of luminophores onto sodium alginate (SA) chains...

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Achieving Efficient Phosphorescence and Mechanoluminescence in Organic Host–Guest System by Energy Transfer

Yang

Shi

et al. 2021

Adv Funct Materials

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Host-guest doping strategy greatly facilitates and expands the scope of construction of organic phosphorescence materials. Herein, triphenylamine with excellent crystallinity is chosen as the host, and four guests with 2-4 triphenylamine repeating units are chosen as the guests. The similarity in molecular structures of the host and guests simplifies the exploration of the luminescence mechanism in the doped system. The doped materials display strong room temperature phosphorescence (RTP) with above 200 ms lifetimes and 30% quantum yields. In addition, the doped system emits blue fluorescence under mechanical stimulation, that is, shows a phenomenon of mechanoluminescence (ML). The experimental results prove that the host plays different roles in different luminescence processes. In the photophosphorescence process, the triplet energy level of the host assists the guest excitons to undergo intersystem crossing. Meanwhile, in the ML process, the energy generated as a result of piezoelectric property of the host crystal is transferred to the guest, causing the guest molecules to emit fluorescence. This work is significant for the construction of doped materials with multiple luminescence properties, including RTP and ML.

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Wide‐Range Color‐Tunable Organic Phosphorescence Materials for Printable and Writable Security Inks

Cited by 372 publications

References 59 publications

Tunable Phosphorescence/Fluorescence Dual Emissions of Organic Isoquinoline‐Benzophenone Doped Systems by Alkoxy Engineering

Tunable Phosphorescence/Fluorescence Dual Emissions of Organic Isoquinoline‐Benzophenone Doped Systems by Alkoxy Engineering

Color‐Tunable, Excitation‐Dependent, and Time‐Dependent Afterglows from Pure Organic Amorphous Polymers

Achieving Efficient Phosphorescence and Mechanoluminescence in Organic Host–Guest System by Energy Transfer

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