External Heavy-Atom Activated Phosphorescence of Organic Luminophores in a Rigid Fluid Matrix

Yan, Zi‐Ang; Ma, Xiang

doi:10.1021/acsmaterialslett.2c01020

Cited by 27 publications

(24 citation statements)

References 52 publications

(61 reference statements)

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“…As for the delayed emission spectrum, the 441 band is completely wiped off, indicating that it is probably a fluorescent state (S 1 ) and the band at room temperature is from thermally activated delayed fluorescence (TADF). [28] To further confirm the conclusion from PL spectra, the luminescence lifetimes of each band were measured at both RT and 77 K. At RT, we found that the fitted lifetime collected at 441 nm has two components, i.e., τ 1 = 1.26 ns and τ 2 = 80.6 ms (Figure S58). At 77 K, a single component of τ 1 = 1.81 ns is present, which clearly points to the TADF mechanism.…”

Section: Resultssupporting

confidence: 53%

Functional Roles of Polymers in Room‐Temperature Phosphorescent Materials: Modulation of Intersystem Crossing, Air Sensitivity and Biological Activity

Huang

et al. 2023

Angewandte Chemie

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Organic room-temperature phosphorescent (RTP) materials routinely incorporate polymeric components, which usually act as non-functional or "inert" media to protect excited-state phosphors from thermal and collisional quenching, but are lesser explored for other influences. Here, we report some exemplary "active roles" of polymer matrices played in organic RTP materials, including: 1) color modulation of total delayed emissions via balancing the population ratio between thermally-activated delayed fluorescence (TADF) and RTP due to dielectric-dependent intersystem crossing; 2) altered air sensitivity of RTP materials by generating various surface morphologies such as nano-sized granules; 3) enhanced bacterial elimination for enhanced electrostatic interactions with negatively charged bio-membranes. These active roles demonstrated that the vast library of polymeric structures and functionalities can be married to organic phosphors to broaden new application horizons for RTP materials.

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Section: Resultssupporting

confidence: 53%

Functional Roles of Polymers in Room‐Temperature Phosphorescent Materials: Modulation of Intersystem Crossing, Air Sensitivity and Biological Activity

Huang

et al. 2023

Angewandte Chemie

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“…However, this does not conform to the conventional principle of heavy atom-enhanced phosphorescence. [51][52][53] Therefore, this further proves the confinement contribution of the inorganic matrix to RTP. The doping of metal ions will affect the change of the inorganic matrix lattice, as confirmed by XRD (Figure 6F and Figure S29).…”

Section: Angewandte Chemiesupporting

confidence: 61%

“…The phosphorescence lifetime is also gradually reduced (Figure S28 and Table S4). However, this does not conform to the conventional principle of heavy atom‐enhanced phosphorescence [51–53] . Therefore, this further proves the confinement contribution of the inorganic matrix to RTP.…”

Section: Resultsmentioning

confidence: 79%

Time‐dependent Phosphorescence Color of Carbon Dots in Binary Salt Matrices through Activations by Structural Confinement and Defects for Dynamic Information Encryption

et al. 2023

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The emergence of time-dependent phosphorescence color (TDPC) materials has taken information encryption to high-security levels. However, due to the only path of exciton transfer, it is almost impossible to obtain TDPC for chromophores with a single emission center. Theoretically, in inorganic-organic composites, the exciton transfer of organic chromophores depends on the inorganic structure. Here, we assign two structural effects to inorganic NaCl by metal (Mg 2 + or Ca 2 + or Ba 2 + ) doping, which triggers the TDPC performance of carbon dots (CDs) with a single emission center. The resulting material is used for multi-level dynamic phosphorescence color 3D coding to achieve information encryption. The structural confinement activates the green phosphorescence of CDs; while the structural defect activates tunneling-related yellow phosphorescence. Such simply doped inorganic matrices can be synthesized using the periodic table of metal cations, endowing chromophores with tremendous control over TDPC properties. This demonstration extends the design view of dynamic luminescent materials.

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“…Ma and Tian et al 44 used a kind of deep eutectic supramolecular polymer (DESP) to prepare supramolecular polymer-based RTP materials (Figure 5b). The transparent DESP 45 was made of hydrogen bonding interaction by using βcyclodextrin as hydrogen bond acceptor and natural organic small molecule acid (malic acid or citric acid) as hydrogen bond donor. The network is rich in hydrogen bonds, making it high viscosity and flowability, which is beneficial for promoting RTP.…”

Section: Supramolecular Polymersmentioning

confidence: 99%

Recent Advances of Pure Organic Room Temperature Phosphorescence Based on Functional Polymers

Ding,

Ma,

Tian

2023

Acc. Mater. Res.

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Conspectus The phosphorescence is produced by the radiative transition of the excited triplet state which is generated by the intersystem crossing (ISC) from the excited singlet state. Compared with fluorescence, it has a longer luminescence lifetime and larger Stokes shift, so phosphorescent materials have great application value in fields such as displays, anticounterfeiting, and imaging. But due to the low ISC rate of organic molecules, the slow radiative transition rate of the triplet state, and the large nonradiative energy loss caused by molecular vibration, pure organic room temperature phosphorescence (RTP) is usually difficult to obtain. Among the most widely used strategies including crystal assembly, polymerization, and host–guest encapsulation, the polymerization strategy based on rigid polymers has achieved great success and widespread attention due to their easy processing and excellent luminescence performance. The main function of polymers is to fix the luminophore into the matrix and suppress the energy loss of the triplet state caused by nonradiative transitions and oxygen quenching. That is, polymers provide a rigid microenvironment necessary for the RTP, although some polymers are flexible and stretchable. Conventional polymers have limited interaction with luminophores and do not have the function of promoting triplet states. Therefore, the high RTP quantum yield depends more on the structural design of luminophores. By modification of the structure, functionalized polymers can be endowed with the ability to regulate the singlet and triplet energy levels of luminophores, enhance ISC, and increase the quantum yield of RTP. The selection of functionalized polymers also enriches the diverse properties of RTP materials. This Account summarizes the latest research progress in the field of polymer-based RTP and RTP enhancement by functionalized polymers. Luminophores are used to construct RTP systems by doping, covalent linking, or supramolecular interactions with polymers such as PAA, PMMA, PVA, and PAM. To further strengthen polymer rigidity, secondary processing has been successfully employed to synergistically suppress nonradioactivation and enhance RTP performance, such as hydrogen bonding bridges, host–guest encapsulation, and cross-linking. The function of polymers is no longer limited to suppressing nonradiative transitions but also includes enhancing the yield of triplet states and generating special luminescence phenomena. A few functionalized polymers are specially designed to utilize external heavy atom effects, dipole–dipole interactions, and electrostatic and diffusion interactions with the luminophores to promote the ISC rate. Due to the diversification and functionalization of polymers, RTP systems were developed with various special luminescence phenomena such as photoactivation, excitation wavelength dependence, photochromism, circularly polarized RTP, and stimulus-response. We hope the summarized functions and development trends of polymers in RTP systems can provide helpful gui...

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External Heavy-Atom Activated Phosphorescence of Organic Luminophores in a Rigid Fluid Matrix

Cited by 27 publications

References 52 publications

Functional Roles of Polymers in Room‐Temperature Phosphorescent Materials: Modulation of Intersystem Crossing, Air Sensitivity and Biological Activity

Functional Roles of Polymers in Room‐Temperature Phosphorescent Materials: Modulation of Intersystem Crossing, Air Sensitivity and Biological Activity

Time‐dependent Phosphorescence Color of Carbon Dots in Binary Salt Matrices through Activations by Structural Confinement and Defects for Dynamic Information Encryption

Recent Advances of Pure Organic Room Temperature Phosphorescence Based on Functional Polymers

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