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Related Concept Videos

  • Engineering
  • Materials Engineering
  • Wearable Materials
  • A High-κ Homogeneous Ink For Printable Electroluminescent Devices.
  • Engineering
  • Materials Engineering
  • Wearable Materials
  • A High-κ Homogeneous Ink For Printable Electroluminescent Devices.

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    A high-κ homogeneous ink for printable electroluminescent devices.

    Tao Li1, Zhengwen Li1, Weilong Chen1

    • 1School of Materials, Shenzhen Campus, Sun Yat-sen University, Shenzhen, China.

    Nature Communications
    |October 10, 2025

    View abstract on PubMed

    Summary
    This summary is machine-generated.

    Researchers developed a printable, transparent ink for flexible electroluminescent devices. This innovation enables low-voltage, high-quality light emission for wearables and soft robotics, paving the way for battery-free applications.

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    Author Spotlight: Quantitative Characterization of Liquid Photosensitive Bioink Properties for Continuous Digital Light Processing Based Printing
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    Area of Science:

    • Materials Science
    • Optoelectronics
    • Polymer Chemistry

    Background:

    • Flexible alternating-current electroluminescent (ACEL) devices offer unique applications but face challenges with low driving voltage, transparency, and pattern clarity due to heterogeneous fillers.
    • Existing high-permittivity fillers (e.g., BaTiO₃, liquid metals) compromise optical properties and pattern definition in ACEL devices.

    Purpose of the Study:

    • To develop a printable, transparent, high-dielectric ink for ACEL devices that overcomes limitations of previous filler materials.
    • To enable efficient, low-voltage operation and scalable fabrication of high-quality, patterned ACEL devices.

    Main Methods:

    • Incorporation of small high-dielectric molecules into a polymer matrix to create a novel ink formulation.
    • Utilized screen printing and one-step photopolymerization for fabricating patterned ACEL devices.
    • Characterized the ink's dielectric properties (constant up to 25) and optical transparency (up to 90%).

    Main Results:

    • Achieved efficient light emission at a low driving voltage of approximately 0.33 V µm⁻¹, among the lowest reported values.
    • Demonstrated excellent printability for scalable, cost-effective patterning of ACEL devices.
    • Fabricated high-quality patterned ACEL devices with high transparency and clarity.

    Conclusions:

    • The developed printable, transparent high-dielectric ink significantly advances ACEL device technology.
    • Enables low-voltage, efficient, and scalable fabrication of flexible electronic devices.
    • Facilitates potential for chip- and battery-free operation through wireless power harvesting.