Overview
🔋 Advanced Energy Storage & Photocapacitor Research
Our research explores innovative materials and device architectures for next-generation energy storage technologies. We develop novel electrode materials for high-performance supercapacitors and batteries, including flexible and wearable energy storage systems. Our work also focuses on solar-driven photocapacitors, membranes and coatings that enhance battery life, and redox flow batteries for large-scale, sustainable energy storage.
Our research focuses on developing next-generation materials and technologies for sustainable, high-performance energy storage systems. We explore novel approaches that bridge the gap between energy harvesting, conversion, and storage — all crucial for meeting the rising demand for clean and reliable power solutions.
Key areas of our work include:
- Novel Electrode Materials: We design and engineer advanced electrode materials to improve the capacity, conductivity, and stability of supercapacitors and batteries.
- Wearable Supercapacitive Materials: With the rise of wearable electronics, we develop lightweight, flexible, and high-performance wearable supercapacitors that maintain energy performance under mechanical stress.
- Integrated Solar-Driven Photocapacitors: We pioneer photocapacitor systems that combine solar energy harvesting and storage into a single device, enabling efficient, real-time energy utilization without the need for external storage units.
- Membranes and Coatings for Long-Cycle-Life Batteries: Our work on functional membranes and protective coatings enhances the lifespan and reliability of battery systems, making them more robust for long-term use.
- Redox Flow Batteries: We explore scalable redox flow battery systems for large-scale energy storage applications, supporting grid stability and renewable energy integration.
By combining materials innovation with system-level engineering, our goal is to develop sustainable, scalable, and multifunctional energy solutions for applications ranging from portable electronics to grid-scale energy storage.