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Home NEWS Science News Chemistry

Unlocking Organic Luminescence: Simultaneous Delayed Fluorescence and Phosphorescence via Multiple Excited States

Bioengineer by Bioengineer
March 30, 2026
in Chemistry
Reading Time: 3 mins read
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Unlocking Organic Luminescence: Simultaneous Delayed Fluorescence and Phosphorescence via Multiple Excited States
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The provided textual and figure descriptions detail the investigation of the photophysical properties of a novel organic emitter, 1.8-mDTAZ-PhtCz, and its derivative 1.8-pDTAZ-PhtCz. Here’s a summary and explanation of key findings and concepts from the study:

1. Fundamental Luminescent Properties of 1.8-mDTAZ-PhtCz

Absorption & Emission:

Absorption peaks at 330-345 nm.
Emission peak at 425 nm in degassed toluene.

Temperature-Dependent Photoluminescence:

Coexistence of prompt fluorescence (PF), thermally activated delayed fluorescence (TADF), and room temperature phosphorescence (RTP).
TADF intensity decreases from room temperature (292 K) down to 252 K, while phosphorescence (phosphorescent emission) dominates at temperatures below 232 K. Phosphorescence remains at 77 K, suggesting long-lived triplet emission at low temperature.

Crystal Structure:

Shows intermolecular hydrogen bonding and π-π stacking contributing to molecular rigidity and suppression of non-radiative decay.
Donor-acceptor twist helps restrict molecular motion, enhancing emission efficiency.

Afterglow:

Ultralong afterglow (phosphorescence) visible up to 42 seconds after turning off UV excitation.

2. Identification of the Second Triplet State (T₂) and Excited-State Dynamics

Nanosecond Transient Absorption (ns-TA):

Reveals three principal excited states with distinct lifetimes: S₁ (singlet), T₂ (second triplet), and T₁ (lowest triplet).
Lifetimes: S₁ ≈ 15.2 ns, T₂ ≈ 2.1 μs, T₁ ≈ 8.2 μs.
T₂ and T₁ have similar spectral energies but notably different decay times, indicating T₂ lies energetically between S₁ and T₁.

Spectral and kinetic analysis support a three-state model describing the decay dynamics during photoluminescence.

3. Theoretical Simulation of Excited States

ROKS Method with LC-ωPBE08 Functional:

Energy order: S₁ (2.978 eV), T₂ (2.953 eV), T₁ (2.912 eV).
Good agreement between calculated and experimental energies.

Electron Density Distribution:

S₁ state exhibits strong charge transfer (CT) with holes localized on the donor (carbazole) and electrons on the acceptor (phenyl-triazine).
T₁ and T₂ states show mixed local excitation (LE) and CT characteristics.
T₂ state’s spatial overlap in hole and electron density facilitates efficient reverse intersystem crossing (rISC) from T₂ back to S₁, critical for TADF.

4. Multi-Channel Emission Dynamics Model

Four-Level Model Incorporating Bimolecular Annihilation:

Emission decay stages span nanoseconds (PF), microseconds (TADF), to milliseconds (RTP).
Models including exciton-exciton annihilation (S₁–S₁, S₁–T₂, T₁–T₁) fit the data best, especially for long-time decay tails.

Excitonic Processes:

PF: Radiative decay of S₁ (~8 ns lifetime).
TADF: rISC from T₂ to S₁ (~10⁻⁷–10⁻⁵ s timescale).
RTP: Radiative decay of T₁ (~0.75 s lifetime), leading to extended phosphorescence.

5. Application: Multi-Color Emission via Förster Resonance Energy Transfer (FRET)

Energy Transfer to Fluorescent Acceptors:

The multi-state excited system transfers energy efficiently from S₁, T₂, and T₁ to doped acceptors: blue (TBPe), green (TTPA), yellow (SYPPV), and red (DCJTB).
Resulting acceptor emission delayed for up to 1.6 s after UV excitation is turned off.

Patterned films demonstrate ultralong persistent multi-color emission, useful for advanced display and anti-counterfeiting applications.

6. Derivative 1.8-pDTAZ-PhtCz: Dual PF and RTP Emission

Structural Modification:

Increased conjugation between donor and acceptor causes a redshift in absorption/emission.

Spectral Shifts:

Absorption onset at 400 nm, fluorescence peak at 430 nm, RTP peak at 523 nm.

Transient Lifetimes:

PF lifetime ~5.2 ns, RTP lifetime extended to 118.7 ms.

ns-TA Spectroscopy:

Still shows S₁, T₂, and T₁ but increased singlet-triplet gap (ΔEST) of 0.3 eV suppresses TADF.

High RTP Quantum Yield:

Achieves 33.6%, significantly higher than typical organic RTP materials.

Summary

The study achieves a detailed understanding of the photophysical processes in a new donor-acceptor organic emitter:

Identifies a second triplet state (T₂) that plays a vital role in enabling efficient TADF through rISC.
Demonstrates complex interplay between PF, TADF, and RTP emissions controlled by temperature and molecular design.
Employs advanced spectroscopic and computational tools to fully elucidate excited state dynamics.
Leverages multi-excited state energy transfer to produce a full visible-spectrum, multi-color delayed emission system.
Tailors molecular structure (derivative 1.8-pDTAZ-PhtCz) to optimize dual PF and RTP emission with high efficiency and long lifetimes conducive to practical applications.

If you need insights on a specific graph panel or want explanations of mechanisms, energy transfer, or kinetic modeling details, feel free to ask!

Tags: donor-acceptor molecular designexcited-state dynamics in organic moleculesintermolecular hydrogen bonding in crystalsmultiple excited states luminescencenanosecond transient absorption spectroscopyorganic luminescencephotophysical properties of organic emittersroom temperature phosphorescence in organicstemperature-dependent photoluminescencethermally activated delayed fluorescence materialsultralong afterglow phosphorescenceπ-π stacking effects on emission

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