logo

[세미나: 10월 6일(금), 오전 10시] Prof. Sungjun Park, Ajou University

Title 

SKIN-COMPATIBLE ORGANIC OPTOELECTRONICS FOR WEARABLE APPLICATIONS

Speaker

Prof. Sungjun Park, Department of Electrical and Computer Engineering, Ajou University

Education

- 2011 ~ 2016 Gwangju Institute of Science and Technology (GIST), Ph. D, MSE, Korea

- 2010 ~ 2011 Gwangju Institute of Science and Technology (GIST), M.S, MSE, Korea

- 2005 ~ 2010 Ajou University, B.S, MSE, Korea

Experience

- 2020 ~ present Assistant Professor, Department of Electrical and Computer Engineering, Ajou University, Suwon, Korea

- 2018 ~ 2020 Senior Researcher, Organic Materials Lab., Samsung Advanced Institute of Technology (SAIT), SAMSUNG, Korea 

- 2017 ~ 2018 Visiting Researcher, Department of Electrical and Electronic Engineering, The University of Tokyo, Japan

- 2016 ~ 2018 Postdoctoral Researcher, Emergent Soft System Research Team Center for Emergent Matter Science RIKEN, Japan

| Date | Friday, October 6, 2023

| Time | 10:00 ~

| Venue | 33동 125호(WCU 다목적실)

[Abstract]

Ultra-flexible organic optoelectronic devices have revolutionized the potential for futuristic biomedical and wearable applications, particularly in the context of the Internet of Things. The remarkable flexibility of organic materials, coupled with their accessible and cost-effective processing methods, has catalyzed the rapid advancement of flexible electronic materials and devices. However, in order to fully realize the potential of these next-generation human-friendly wearable devices and sensors, it is imperative to further investigate the enhancement of electronic functions and mechanical stability. In this presentation, I will provide a comprehensive review of recent breakthroughs as well as the remaining challenges in the field of ultra-flexible organic electronics. The focus will be on discussing the preliminary results achieved through appropriate material selection and structure engineering, which aim to develop energy harvesters and sensors that are compatible with human skin. It is crucial to ensure that these devices maintain their photonic and electrical performances even under external mechanical stresses. By disseminating our findings, we aim to inspire further research that contributes to the growth of ultra-flexible electronics in various domains, including wearables, primary healthcare, medical applications, and motion recognition for AR/VR. Through continuous exploration and innovation, we can unlock new opportunities to seamlessly integrate advanced electronics into our daily lives, ultimately enhancing human well-being and pushing the boundaries of technological possibilities.

| Host | 강승균 교수(02-880-5756)