In a groundbreaking advancement for organic luminescent materials, researchers have unveiled a novel mechanism that harnesses simultaneous delayed fluorescence and phosphorescence within a single organic compound, a feat accomplished by exploiting multiple excited states. This innovative approach, detailed in the recent publication by Dou, Liu, Zhou, and colleagues in Light: Science & Applications, heralds a new frontier in the design and optimization of organic light-emitting materials with profound implications for next-generation display technology, organic lasers, and bioimaging.
Traditionally, organic luminescent materials have been classified based on their ability to exhibit either fluorescence or phosphorescence, two fundamentally different types of light emission originating from distinct excited-state processes. Fluorescence involves the prompt emission of photons as excited electrons return to the ground state, typically within nanoseconds. In contrast, phosphorescence arises from the slower relaxation of electrons trapped in a triplet excited state, extending emission lifetimes into microseconds and beyond. The ability to simultaneously manipulate both these emissive pathways within a single material platform has long challenged scientists due to the conflicting time scales and spin multiplicities involved.
The research team addressed this challenge by designing an organic luminescent system that strategically incorporates multiple excited states, thereby enabling efficient intersystem crossing and reverse intersystem crossing mechanisms in tandem. By fine-tuning the molecular architecture, they successfully achieved a material where delayed fluorescence—a form of thermally activated delayed fluorescence (TADF)—and phosphorescence coexist. This dual emission process was demonstrated under ambient conditions, a critical criterion for practical applications.
Central to this revelation is the molecular engineering that balances singlet and triplet excited states, allowing the material to harness triplet excitons that traditionally remain non-radiative or contribute to phosphorescence only. In this system, the conversion of triplet excitons back to singlet states facilitates delayed fluorescence. Concurrently, a portion of the triplet population emits directly through phosphorescence. The concurrency of these radiative decay channels is meticulously controlled through quantum yield optimization and excited state energy alignment.
The implications of this discovery extend beyond fundamental photophysics to real-world applications. Organic light-emitting diodes (OLEDs), a technology increasingly pervasive in modern display and lighting systems, stand to benefit significantly. By leveraging both delayed fluorescence and phosphorescence, devices can attain higher internal quantum efficiencies without relying on heavy metal dopants, which are not only costly but pose environmental concerns. This all-organic approach promises more sustainable and efficient OLED designs.
Moreover, the ability to tune the emission via multiple excited states opens new possibilities for color purity and tunability in lighting applications. Traditional phosphorescent materials often suffer from spectral broadening or color instability, while pure fluorescence emitters may lack efficiency. The dual mechanism stabilizes emission profiles and enhances brightness, potentially enabling customizable, high-resolution displays and adaptive lighting systems responsive to environmental inputs.
In the realm of bioimaging, organic compounds exhibiting prolonged emission lifetimes, namely through delayed fluorescence and phosphorescence, can significantly improve imaging resolution and contrast by minimizing background fluorescence. This allows for time-gated imaging techniques that isolate the desired luminescent signals, an advantage this new material system could amplify, offering more sensitive diagnostic tools and real-time bio-probes.
The authors employed an array of spectroscopic techniques to unravel the material’s excited-state dynamics, including time-resolved photoluminescence and transient absorption measurements, validating the coexistence of delayed fluorescence and phosphorescence with distinct temporal profiles. Their rigorous characterization ensures that the observed dual emission is intrinsic to the molecular design rather than an artifact of environmental variations or impurities.
Additionally, computational studies using quantum chemical calculations provided insight into the energy landscape and spin-orbit coupling effects governing intersystem crossing rates. The simulations guided the rational design of molecular entities with appropriate singlet-triplet energy gaps, a critical parameter for efficient reverse intersystem crossing that underpins delayed fluorescence.
This research represents a paradigm shift in the understanding and utilization of organic luminescent materials. By demonstrating control over multiple excited states to enable concurrent delayed fluorescence and phosphorescence, it redefines the boundaries of organic optoelectronics. The ability to engineer materials with tailored emission kinetics and spectral properties unlocks synergies previously deemed incompatible within a single molecular platform.
Future directions proposed by the team include expanding the molecular library of such dual-emissive compounds and integrating these materials into functional devices to test performance under operational conditions. They highlight the promise of this approach not only in OLEDs but also in organic lasers, sensing devices, and luminescent solar concentrators, suggesting a broad technological impact.
Challenges remain, particularly in scaling synthesis, ensuring long-term stability, and optimizing emission efficiency across the visible spectrum. However, the foundational knowledge established in this study offers a research roadmap toward overcoming these hurdles. Collaborative efforts bridging chemistry, physics, and engineering will be pivotal in translating this molecular innovation into commercial products.
In essence, Dou and colleagues’ breakthrough underscores the power of rational molecular design combined with mechanistic insight to circumvent limitations inherent in organic luminescent materials. This work exemplifies how a nuanced understanding of excited-state multiplicities and their interplay can be leveraged to craft materials with unprecedented photophysical properties, influencing a spectrum of scientific and industrial fields.
As the demand for sustainable, efficient, and versatile lighting and display technologies intensifies, such advances underscore the critical role of fundamental science in driving innovation. The confluence of delayed fluorescence and phosphorescence within a singular organic emitter charts a new course for the next generation of luminescent materials, heralding a future where organic electronics can achieve previously unattainable levels of performance and functionality.
Subject of Research:
Organic luminescent materials exhibiting simultaneous delayed fluorescence and phosphorescence through multiple excited states.
Article Title:
Simultaneous delayed fluorescence and phosphorescence in organic luminescent material employing multiple excited states.
Article References:
Dou, D., Liu, W., Zhou, X. et al. Simultaneous delayed fluorescence and phosphorescence in organic luminescent material employing multiple excited states. Light Sci Appl 15, 4 (2026). https://doi.org/10.1038/s41377-025-02063-x
Image Credits:
AI Generated
DOI:
01 January 2026
Tags: advancements in photonicsbioimaging applicationsdesign of luminescent materialsdual delayed fluorescenceexcited state processes in luminescenceintersystem crossing in luminescencenext-generation display technologyorganic lasers developmentorganic light-emitting technologyorganic luminescent materialsphosphorescence in organic compoundssimultaneous emission mechanisms
