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Paving the Way for Advanced Wearable Display Technologies

HKUST Engineering Researchers Developed Full-Color Fiber LEDs Based on Perovskite Quantum Wires

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Photoluminescence of flexible full-color Fi-LEDs: I ♥ HKUST pattern (left) and “night scene” of Victoria Harbor showing color transition (right), built by mounting batches of fibers.
Photoluminescence of flexible full-color Fi-LEDs: I ♥ HKUST pattern (left) and “night scene” of Victoria Harbor showing color transition (right), built by mounting batches of fibers. [Download Photo]
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A research team led by the School of Engineering of the Hong Kong University of Science and Technology (HKUST) has developed full-color fiber light-emitting diodes utilizing perovskite quantum wires (PeQWs), paving the way for innovative wearable lighting and display devices.

Fiber light-emitting diodes (Fi-LEDs) stand out as a key component in the realm of flexible LEDs because of their compatibility with textile fabrication and excellent spatial luminance uniformity. Metal halide perovskites (MHPs) have emerged as promising light-emitting materials for next-generation LEDs due to their superior optoelectronic properties. Despite the potential, the fabrication of MHP-based Fi-LEDs has faced challenges such as gravity- and surface tension-induced nonuniform coating, low-quality crystallization, and complex electrode deposition processes, which all culminate in uneven and inefficient light emission.

To tackle these issues, the research team led by Prof. FAN Zhiyong, Chair Professor at HKUST’s Department of Electronic & Computer Engineering and Department of Chemical & Biological Engineering, employed a novel approach using porous alumina membrane (PAM) templates on thin aluminum fibers. The PAM, with an ultrasmall pore size of approximately 5 nm, was fabricated on aluminum fibers using a roll-to-roll solution-coating process. The MHP precursor solution was filled into the PAM channels, followed by a surrounding annealing procedure to ensure spatially uniform solvent vaporization and MHP crystallization. This method enables the uniform growth of PeQW arrays and minimizes the formation of unwanted thin-film structures on the PAM surface.

The research team successfully demonstrated the fabrication of full-color Fi-LEDs with emission peaks at 625 nm (red), 512 nm (green), and 490 nm (sky-blue). The fabricated fibers exhibited good bendability and stretchability, making them suitable for textile lighting applications. Various 2D and 3D architectures were showcased, including a 2D full-color string “I ♥ HKUST”, all with excellent fluorescence uniformity. Additionally, a “night scene” of Victoria Harbor was created using PeQWs with halide gradient-induced color transitions, highlighting the versatility and aesthetic potential of the Fi-LEDs.

This work presents a significant advancement in the field of Fi-LEDs. Future developments could focus on enhancing the efficiency and stability of the Fi-LEDs, exploring new perovskite compositions for a broader range of emission colors, and integrating these devices into commercial textile products.

“The combination of quantum confinement effect and the passivation from the 3D porous alumina membrane structure has enabled us to achieve outstanding photoluminescence and electroluminescence efficacy. Our innovative approach for fiber LEDs opens up new possibilities for fabricating unconventional 3D-structured lighting sources, paving the way for advanced wearable display technologies,” said Prof. Fan.

The research work was published in first-rate multidisciplinary journal Science Advances entitled “Full-Color Fiber Light-Emitting Diodes Based on Perovskite Quantum Wires”. Electronic and Computer Engineering PhD student REN Beitao is the first author, and Prof. Fan is the corresponding author. Other co-authors include PhD students and postdoc researchers in Prof. Fan’s group and collaborators in Sun Yat-sen University and Nanjing University of Science and Technology.

For media inquiries, please contact:

Celia Lee
Tel: 2358 8982 / Email: celialee@ust.hk

Dorothy Yip
Tel: 2358 5917/ Email: egkkyip@ust.hk

(This article was originally published on EurekAlert on August 12, 2024.)