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Welcome to the Advanced Multifunctional Nanocomposite Lab (AMNL)!
At AMNL, we are dedicated to pioneering research in the development of novel nanocomposites with exceptional mechanical, thermal, and electrical properties. Our major research focuses include:
Conductive Nanocomposites
We are at the forefront of developing advanced conductive nanocomposites that combine high conductivity with robust mechanical properties. These materials have wide-ranging applications in electronics, energy storage, and beyond.
Thermal Rectification
Our research in thermal rectification aims to create materials that can control heat flow in innovative ways. These materials are crucial for enhancing the efficiency of thermal management systems in various technological applications.
Thermal Interface Materials
We are innovating thermal interface materials (TIMs) that offer superior thermal conductivity and mechanical stability. These TIMs are essential for improving the performance and longevity of electronic devices by efficiently managing heat dissipation. Join us as we explore the cutting-edge of nanocomposite science to develop materials that meet the demands of modern technology.
Research 01
Conductive nanocomposites blend conductive nanoparticles, such as carbon nanotubes or graphene, with a host matrix to boost electrical conductivity. They enable enhanced electron flow for improved conductivity, used in applications like shielding, antistatic coatings, sensors, and adhesives.
Research 02
Thermal rectification is a process where heat flows more easily in one direction than the opposite within a material, similar to how an electrical diode works for current flow. This allows for directional heat transfer, useful in thermal management and energy conversion technologies.
Research 03
Thermal interface materials (TIMs) improve heat transfer between components by filling air gaps and reducing thermal resistance. Available as pastes, pads, tapes, or phase change materials, they're vital for cooling electronics, enhancing device performance and longevity.