[Device Physics & Performance Optimization]
We explore the fundamental limits of electronic devices, focusing on charge injection and transport dynamics. Our research aims to bridge the gap between ideal material properties and real-world device performance by mitigating non-ideal factors—such as interfacial defects, fabrication process variations, and surface impurities. By understanding these nanoscale physical phenomena, we engineer optimized material interfaces to realize high-performance, energy-efficient hardware platforms for next-generation computing.
[Unconventional Electronics & Multi-Dimensional Interfaces]
As a distinct and independent research thrust, we develop unconventional, form-factor-free electronics designed to seamlessly integrate with complex, non-planar surfaces. Moving beyond rigid, conventional hardware, our group engineers flexible, stretchable, and conformable electronic systems. These technologies serve as multi-dimensional interfaces capable of wrapped integration on curved structures, including biological tissues and robotic systems, enabling advanced sensing, actuation, and seamless human-machine-environment interaction.