Cool run: liquid metal polymers heat up electronics performance
en-GBde-DEes-ESfr-FR

Cool run: liquid metal polymers heat up electronics performance

30/10/2024 TranSpread

Effective thermal management is essential to ensuring the performance and lifespan of modern electronics. While polymers are widely used in electronic components, they inherently exhibit poor thermal conductivity, limiting their effectiveness in dissipating heat. To overcome this, researchers have been investigating the potential of integrating highly conductive fillers, such as liquid metals (LM), into polymers. However, stable dispersion and strong interfacial bonding between polymer matrices and liquid metal fillers have proven difficult to achieve, underscoring the need for further research into advanced composite materials capable of enhancing thermal properties while maintaining mechanical integrity.

A team from Sichuan University, led by Professor Hua Deng, published a study (DOI: 10.1007/s10118-024-3144-2) in the Chinese Journal of Polymer Science on May 21, 2024, showcasing a new method for producing high-performance polymer composites containing liquid metal. The researchers developed a novel technique that significantly improves the thermal conductivity of polymers by enhancing the interaction between liquid metal particles and the polymer matrix. Their findings provide valuable insights into addressing the heat dissipation requirements of high-power electronics.

The study introduces a new process called "shear-induced precipitation-interfacial reset-reprotonation." This innovative approach successfully disperses liquid metal particles within the polymer matrix, overcoming previous challenges related to particle dispersion and interfacial compatibility. The team used aramid micron fibers (AMFs) as the foundation for their composites, inspired by the dendritic structure of tree roots to enhance stability and dispersion. By carefully controlling pH during protonation, the researchers ensured optimal bonding between AMFs and liquid metal particles. The resulting AMFs-pH/LM films achieved a thermal conductivity of 10.98 W·m−1·K−1, a 126.8% improvement over conventional polymer composites. Additionally, the films demonstrated excellent mechanical properties, including a tensile strength of approximately 85.88 MPa, making them ideal for use in high-power electronics where durability and efficient heat dissipation are crucial. This advancement represents a significant step forward in the development of multifunctional polymer composites for industrial applications.

"Our approach not only enhances the thermal conductivity of polymer composites but also preserves their mechanical strength," said Professor Hua Deng, the study’s lead author. "By stabilizing liquid metal particles within the polymer matrix, we are opening new possibilities for materials used in electronics and other industries where effective heat management is critical. This technique could lead to more efficient thermal management solutions in the future."

The potential applications of this research extend far beyond electronics. The AMFs-pH/LM composite films could be utilized in industries requiring materials that withstand both mechanical stress and efficient heat dissipation, such as high-power light emitting diode (LED) lighting, flexible electronics, and wearable devices. Furthermore, the innovative method presented in the study could inspire new advances in composite material design, paving the way for more sustainable and energy-efficient solutions across various technology sectors.

###

References

DOI

10.1007/s10118-024-3144-2

Original Source URL

https://doi.org/10.1007/s10118-024-3144-2

Funding information

This work was financially supported by the National Key Research & Development Plan (No. 2022YFA1205200).

About Chinese Journal of Polymer Science

Chinese Journal of Polymer Science (CJPS) is a monthly journal published in English and sponsored by the Chinese Chemical Society and the Institute of Chemistry, Chinese Academy of Sciences. CJPS is edited by a distinguished Editorial Board headed by Professor Qi-Feng Zhou and supported by an International Advisory Board in which many famous active polymer scientists all over the world are included. Manuscript types include Editorials, Rapid Communications, Perspectives, Tutorials, Feature Articles, Reviews and Research Articles. According to the Journal Citation Reports, 2023 Impact Factor (IF) of CJPS is 4.1.

Paper title: An Effective Approach for the Preparation of High Performance Thermal Conductive Polymer Composites Containing Liquid Metal
Attached files
  • Innovative Process for Fabricating AMFs-pH/LM Films with Enhanced Thermal Conductivity and Stability.
30/10/2024 TranSpread
Regions: North America, United States, Asia, China
Keywords: Science, Chemistry

Disclaimer: AlphaGalileo is not responsible for the accuracy of news releases posted to AlphaGalileo by contributing institutions or for the use of any information through the AlphaGalileo system.

Testimonials

For well over a decade, in my capacity as a researcher, broadcaster, and producer, I have relied heavily on Alphagalileo.
All of my work trips have been planned around stories that I've found on this site.
The under embargo section allows us to plan ahead and the news releases enable us to find key experts.
Going through the tailored daily updates is the best way to start the day. It's such a critical service for me and many of my colleagues.
Koula Bouloukos, Senior manager, Editorial & Production Underknown
We have used AlphaGalileo since its foundation but frankly we need it more than ever now to ensure our research news is heard across Europe, Asia and North America. As one of the UK’s leading research universities we want to continue to work with other outstanding researchers in Europe. AlphaGalileo helps us to continue to bring our research story to them and the rest of the world.
Peter Dunn, Director of Press and Media Relations at the University of Warwick
AlphaGalileo has helped us more than double our reach at SciDev.Net. The service has enabled our journalists around the world to reach the mainstream media with articles about the impact of science on people in low- and middle-income countries, leading to big increases in the number of SciDev.Net articles that have been republished.
Ben Deighton, SciDevNet

We Work Closely With...


  • BBC
  • The Times
  • National Geographic
  • The University of Edinburgh
  • University of Cambridge
  • iesResearch
Copyright 2024 by AlphaGalileo Terms Of Use Privacy Statement