Triboelectric Nanogenerator
One of the major focus areas of our research in the development of Triboelectric Nanogenerators (TENGs). We delve into pioneering advancements that harness the intriguing phenomenon of triboelectricity to revolutionize energy harvesting technologies. Through innovative design and material engineering, our work aims to enhance the efficiency, scalability, and practicality of TENGs as sustainable power sources for practical industrial applications. With a focus on developing cutting-edge materials, polymers, and novel device concept we strive to contribute to the transformative landscape of renewable energy generation and pave the way for a more self-sufficient and sustainable future.
Energy
Piezoelectric Nanogenerator
In the realm of piezoelectric nanogenerators, our research is at the forefront of developing novel materials and developing novel strategies to improve the energy harvesting performance. Our investigations are centred around understand the ferroelectric and piezoelectric properties of intrinsic piezoelectric materials. We strive to push the boundaries of piezoelectric nanogenerators, in terms of enhancing their efficiency, reliability, and adaptability for diverse applications.
Self-powered Supercapacitor
In terms of energy storage, we specifically aim at merging energy storage and harvesting capabilities. Our efforts are concentrated on engineering advanced supercapacitor technologies that not only store energy efficiently but also seamlessly integrate with ambient energy sources for self-sustaining operation. Through innovative material design, electrode architecture, and charge management strategies, we are pushing the boundaries of self-powered supercapacitors to enable simultaneous energy storage and generation from environmental sources such as solar radiation, mechanical vibrations, and thermal gradients.
Electronics
Stretchable & Self-healing Electronics
In the dynamic realm of stretchable and self-healing electronics, our research is dedicated to pioneering transformative advancements that fuse mechanical resilience with autonomous recovery in electronic systems. Our work focuses on the development of cutting-edge materials and innovative design strategies that empower electronics to not only endure substantial strains and deformations but also possess intrinsic self-healing capabilities for next-generation skin-inspired electronics.
Wearable Electronics
We focused to seamlessly integrating cutting-edge next-generation electronic devices technology into the fabric of everyday life. Our focus lies in the development of stretchable, comfortable, and adaptable electronic systems that harmonize with the human body's movements and contours. Through pioneering materials selection, advanced fabrication techniques, and ergonomic design principles, we aim to create wearable devices that not only offer high-performance functionality but also ensure user comfort and convenience.
BioElectronics
In the burgeoning field of bioelectronics, our research endeavors encompass groundbreaking exploration at the crossroads of biology and electronics. Our work encompasses the development of cutting-edge self-powered biosensors enabling real-time monitoring, diagnostics, and therapeutic.
