In a groundbreaking advance poised to revolutionize photonics and optoelectronics, a team of researchers has demonstrated electrically driven lasing from a uniquely designed dual-cavity perovskite device. This innovation marks a significant milestone in the quest for compact, efficient, and low-threshold laser sources that can operate under ambient conditions. By ingeniously integrating a low-threshold single-crystal perovskite microcavity with a high-power microcavity perovskite light-emitting diode (PeLED), the scientists created a vertically stacked multilayer structure that elevates the capabilities of perovskite semiconductors into the realm of electrically driven lasing.
The core mechanism enabling this lasing behavior lies in the synergy between the dual-cavity components. The high-power microcavity PeLED sub-unit acts as an optical pump, delivering concentrated light into the single-crystal perovskite microcavity sub-unit. This integrated architecture boasts a remarkable optical coupling efficiency of 82.7%, an attribute crucial to achieving lasing action at low electrical input thresholds. Under pulsed electrical excitation at room temperature in ambient air, the device exhibits a minimum lasing threshold of just 92 amperes per square centimeter, with an average threshold of 129 A/cm². Such performance not only outstrips previous perovskite-based electrically pumped lasers but also sets a new benchmark by delivering an order of magnitude improvement over state-of-the-art organic electrically driven lasers.
Critical to the validation of genuine lasing were the meticulous investigations into key optical parameters. The research team focused on a spectrum of defining lasing characteristics: evident thresholds, sharp linewidth narrowing, polarization-dependent emission, and distinct beam profiles, all measured using established rigorous protocols. These observations confirmed that the emission results from coherent stimulated emission rather than spontaneous luminescence or amplified spontaneous emission, thereby conclusively proving the device’s capacity for electrically driven lasing.
One of the most distinctive attributes of this work is the strategic employment of the dual-cavity configuration. This architectural innovation enables a division of functionality within the device: the PeLED microcavity generates substantial optical power with high efficiency, while the single-crystal perovskite cavity exploits this power to sustain coherent lasing. When compared to a similar device architecture limited to a single cavity, the dual-cavity design reduces the required lasing threshold by approximately 4.7 times, a remarkable improvement that underscores the advantages of optical-electric integration within nanoscale device engineering.
Beyond threshold performance, the stability and operational lifespan of electrically driven lasers have long posed formidable challenges for practical application. The presented dual-cavity perovskite laser device addresses these hurdles head-on, demonstrating a half-life (T_50) of 1.8 hours under consistent pulsed operation at 10 Hz frequency, corresponding to more than 64,000 voltage pulses. This level of operational stability surpasses that observed in organic electrically driven lasers, suggesting the device’s notable promise for long-term usage in real-world photonic systems where sustained reliability is paramount.
Further enhancing its appeal for technological exploitation is the device’s rapid modulation capability. With a modulation bandwidth measured at 36.2 megahertz, the laser exhibits potential for high-speed data transmission, signaling its compatibility with emerging communication protocols and photonic computing architectures. This fast modulation speed, combined with the low threshold and ambient stability, suggests that these perovskite lasers are well-suited for applications demanding quick and efficient light source modulation.
In light of its innovation, the dual-cavity perovskite laser represents a major breakthrough not only in fundamental laser physics but also in applied photonics. Perovskite materials are already celebrated for their excellent optoelectronic properties, including high photoluminescence quantum yield, tunable bandgaps, and facile fabrication. The successful realization of electrically pumped lasing directly taps into these material advantages, creating a pathway towards an entirely new class of compact, integrated light sources that could be embedded into devices for a range of applications from data communication to biomedical imaging.
The research showcases the power of material and device engineering synergy. By leveraging single-crystal perovskite microcavities—known for their superior optical quality and low defect densities—coupled with high-brightness PeLEDs, the team surmounted prior limitations that had hindered efficient electrical lasing. This convergence of high-efficiency charge injection and optical feedback mechanisms opens new directions for solid-state laser development, particularly those needing miniaturization without compromising performance.
Moreover, the device’s ability to operate under pulsed electrical excitation at room temperature and in air enhances its prospects for practical integration. Unlike many lasers that require vacuum or cryogenic conditions, this perovskite laser maintains performance stability in everyday environmental conditions, a critical factor for commercialization and scalable manufacturing.
From a device fabrication perspective, the vertical stacking method offers a modular strategy to combine different functional units with optimized interfaces and tailored optical properties. This layered architecture may serve as a blueprint for future optoelectronic devices that demand multifunctionality, combining emission, modulation, and sensing functionalities into a single platform.
While further research is imperative to extend the operational lifetime and explore continuous-wave lasing regimes, this breakthrough sets the stage for developing electrically driven lasers that leverage perovskite semiconductors’ unique advantages. Such devices could dramatically impact fields requiring coherent light sources with compact footprints, such as on-chip photonic circuits, lab-on-a-chip devices, and wearable health-monitoring technologies.
Overall, the work represents a landmark achievement in perovskite photonics and electrically pumped lasing, addressing long-standing challenges in threshold reduction, stability, and operational practicality. It highlights the transformative potential of dual-cavity architectures to reshape how lasers are designed and integrated into future technologies. By unlocking the ability to drive lasing electrically in perovskites with high efficiency and stability, the researchers open avenues for next-generation light sources that may become ubiquitous in communications, computation, and beyond.
Subject of Research: Electrically driven lasing in perovskite semiconductor devices with dual-cavity architecture.
Article Title: Electrically driven lasing from a dual-cavity perovskite device.
Article References:
Zou, C., Ren, Z., Hui, K. et al. Electrically driven lasing from a dual-cavity perovskite device. Nature (2025). https://doi.org/10.1038/s41586-025-09457-2
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