Oxide Interfaces

The Oxide Interfaces Research Group is dedicated to investigating the physicochemical properties of oxide material surfaces/interfaces, interface regulation mechanisms, and their innovative applications in energy-related fields. By focusing on the correlation between microscopic interface science and macroscopic performance, we aim to provide theoretical and experimental foundations for the design of novel functional materials and the development of advanced devices.

Research Focus

1. Interface Dynamic Mechanisms
   • In situ characterization of electrochemistry and atomic-scale structures in oxide single-crystal thin films
   • Interfacial charge transport mechanisms
   • Surface/interface defect engineering and performance optimization theories
2. Frontier Application Fields
   • Oxide semiconductor interfaces (e.g., photo/electrocatalysis, sensors)
   • Solid-state electrolyte interfaces (e.g., lithium-ion batteries, fuel cells)
3. Advanced Techniques
   • In situ characterization technologies: scanning tunneling microscopy (STM), atomic force microscopy (AFM), etc.
   • First-principles calculations and machine learning molecular dynamics simulations
   • Precision fabrication techniques: pulsed laser deposition (PLD), etc.

Team Strengths

• Interdisciplinary Collaboration: We bring together experts in physical chemistry, computational chemistry, condensed matter physics, and materials science to conduct multidimensional research on interfaces.
• Industry-Academia-Research Integration: Collaborations with domestic and international top-tier laboratories strengthen the bridge between fundamental research and practical applications.
• Innovation-Driven Culture: We encourage exploratory research topics and prioritize fostering independent scientific thinking and technical capabilities