Research Details
Aims of Research
My research spans multiple disciplines, including the design of bioinspired flexible and stretchable electronics, advanced sensing systems, and the integration of machine learning with innovative materials.
The primary aim is to develop next-generation hybrid electronics that seamlessly integrate rigid, flexible, and stretchable components. These technologies will address critical challenges in healthcare, human–machine interfaces, and environmental monitoring, enabling the creation of durable, highly stretchable platforms for wearable systems and beyond.
Through the integration of intelligent algorithms and advanced fabrication techniques, my work aims to bridge the gap between hardware and artificial intelligence, paving the way for groundbreaking applications such as stretchable displays, real-time diagnostic tools, and multifunctional electronic skins.
1) Bioinspired Designs for Flexible and Stretchable Electronics
Inspired by natural systems, my research introduces bioinspired interfacial engineering approaches to enhance the durability, stretchability, and functionality of hybrid electronic platforms [1, 2]. These designs address the challenges of integrating rigid, flexible, and stretchable components by mimicking natural structures such as plant roots. These bioinspired strategies pave the way for the next generation of stretchable electronics by offering solutions to interfacial challenges while maintaining high mechanical reliability and scalability.
1) Nature Communications, 2025
2) Small, 2025
2) Artificial Intelligence (AI) for Advanced Sensing Systems
My research extends to the integration of AI and machine learning techniques with sensor technologies, enabling real-time data processing, predictive capabilities, and enhanced system performance. This work focuses on employing AI to extract meaningful insights from sensor data for applications such as human-machine interfaces and environmental monitoring [3, 4]. These efforts aim to bridge the gap between sensor technologies and intelligent systems, contributing to advancements in automation, safety, and healthcare.
3) Adv. Mater. Technol. 2024, 9, 2302134
4) Small Methods 2023, 2201352
3) Advanced Sensors for Wearable Applications
I have conducted research on designing and fabricating advanced sensors tailored for wearable and healthcare applications. My focus has been on developing innovative liquid-metal-based sensors with diverse geometries and functionalities, such as dome structures and piezo-transmittance designs. These sensors exhibit excellent sensitivity, mechanical flexibility, and scalability for various applications [5, 6, 7, 8]. These advancements aim to revolutionize wearable technologies by enhancing sensor performance, user adaptability, and integration into healthcare systems.
5) IEEE Transactions on Biomedical Circuits and Systems, vol. 17, no. 5, pp. 889-899, Oct. 2023
6) Nano Energy, 2023, 109, 108299
7) ACS Applied Electronic Materials 2021, 3, 9, 4027–4036
8) Micro and Nano Systems Letters volume 9, Article number: 2 (2021)
Osman Gul 