Your search keyword '"Park, Kwonpil"' showing total 3 results

1. Advancements in Flexible and Stretchable Electronics for Resistive Hydrogen Sensing: A Comprehensive Review.

Author

Park, Kwonpil and Kim, Minsoo P.

Subjects

*FLEXIBLE electronics, *SENSOR networks, *HYDROGEN detectors, *TECHNOLOGICAL innovations, *CLEAN energy, *POWER electronics

Abstract

Flexible and stretchable electronics have emerged as a groundbreaking technology with wide-ranging applications, including wearable devices, medical implants, and environmental monitoring systems. Among their numerous applications, hydrogen sensing represents a critical area of research, particularly due to hydrogen's role as a clean energy carrier and its explosive nature at high concentrations. This review paper provides a comprehensive overview of the recent advancements in flexible and stretchable electronics tailored for resistive hydrogen sensing applications. It begins by introducing the fundamental principles underlying the operation of flexible and stretchable resistive sensors, highlighting the innovative materials and fabrication techniques that enable their exceptional mechanical resilience and adaptability. Following this, the paper delves into the specific strategies employed in the integration of these resistive sensors into hydrogen detection systems, discussing the merits and limitations of various sensor designs, from nanoscale transducers to fully integrated wearable devices. Special attention is paid to the sensitivity, selectivity, and operational stability of these resistive sensors, as well as their performance under real-world conditions. Furthermore, the review explores the challenges and opportunities in this rapidly evolving field, including the scalability of manufacturing processes, the integration of resistive sensor networks, and the development of standards for safety and performance. Finally, the review concludes with a forward-looking perspective on the potential impacts of flexible and stretchable resistive electronics in hydrogen energy systems and safety applications, underscoring the need for interdisciplinary collaboration to realize the full potential of this innovative technology. [ABSTRACT FROM AUTHOR]

Published

2024

2. In Situ Analysis of Binder Degradation during Catalyst-Accelerated Stress Test of Polymer Electrolyte Membrane Fuel Cells.

Author

Yoo, Donggeun, Park, Sujung, Oh, Sohyeong, Kim, Minsoo P., and Park, Kwonpil

Subjects

PROTON exchange membrane fuel cells, CATALYST supports, IMPEDANCE spectroscopy, CYCLIC voltammetry, SCANNING electron microscopy

Abstract

High-oxygen-permeability ionomers (HOPIs) are being actively developed to enhance the performance and durability of high-power polymer electrolyte membrane fuel cells (PEMFCs). While methods for evaluating binder performance are well-established, techniques for assessing binder durability and measuring its degradation in situ during the AST process remain limited. This study examines the distribution of relaxation times (DRT) and Warburg-like response (WLR) methods as in situ analysis techniques during the catalyst-accelerated stress test (AST) process. We conducted catalyst-ASTs (0.6–0.95 V cycling) for 20,000 cycles, monitoring changes using cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), and linear sweep voltammetry (LSV). Contrary to expectations, during the catalyst-AST, the ion transport resistance of the binder decreased, indicating no binder degradation. Scanning electron microscopy/energy dispersive spectrometer (SEM/EDS) analysis revealed that the degradation rate of the catalyst and the support was relatively higher than that of the binder, leading to a reduction in catalyst layer thickness and improved binder network formation. By applying the DRT method during the catalyst-AST process, we were able to measure the increase in oxygen reduction reaction (ORR) resistance and the decrease in proton transport resistance in situ. This allowed for the real-time detection of the reduction in catalyst layer thickness and improvements in ionomer networks due to catalyst and support degradation. These findings provide new insights into the complex interplay between catalyst degradation and binder performance, contributing to the development of more durable PEMFC components. [ABSTRACT FROM AUTHOR]

Published

2024

3. Study on accelerated stress test and degradation for open cathode stack in polymer electrolyte membrane fuel cell.

Author

Yoo, Donggeun and Park, Kwonpil

Subjects

*CELL membrane formation, *OSTWALD ripening, *TRANSMISSION electron microscopy, *ELECTRODE testing, *CATALYST supports, *PROTON exchange membrane fuel cells, *IONOMERS

Abstract

The open cathode polymer electrolyte membrane fuel cell stack has some challenges in performance and durability. Especially, study on the durability of open cathode stacks remains insufficient, and there is no established evaluation method for open cathode stack. In this study, 13-cell open cathode stack is conducted startup/shutdown (SU/SD) constant current (CC) and SU/SD load cycle (LC), and polarization curve and electrochemical impedance spectroscopy of stack changes are observed. After the durability test protocol, the stack is dismantled, and the cause of degradation was analyzed using cyclic voltammetry, distribution relaxation times (DRT), X-ray diffraction (XRD), and transmission electron microscopy (TEM), depending on the positions of the cell and membrane electrode assembly. The SU/SD LC protocol shows over 40 % degradation in stack performance with 800 cycles fewer durability test than the SU/SD CC protocol. As a result, The SU/SD LC protocol shows a 44 % acceleration compared to the SU/SD CC protocol, resulting in a reduction of evaluation time by 127 h. Based on electrochemical surface area, double layer capacitance, XRD, and TEM analysis results, it is determined that the accelerated degradation of SU /SD LC protocol is caused by a combination of catalyst and catalyst support degradation induced Ostwald ripening and agglomeration. • Startup/shutdown (SU/SD) test protocols were conducted on the open cathode stack. • The load cycling (LC) accelerated the degradation rate of SU/SD protocol by 44 %. • Load cycling promoted ECSA decrease and catalyst particle growth at the outlet. • Degradation of the binder ionomer was observed at the outlet through DRT analysis. • The SU/SD LC protocol accelerated the catalyst layer degradation of the outlet. [ABSTRACT FROM AUTHOR]

Published

2024