Your search keyword '"David B. Ahn"' showing total 4 results

1. On-demand solid-state artistic ultrahigh areal energy density microsupercapacitors

Author

Ju-Won Lee, Kwon-Hyung Lee, Seong-Sun Lee, David B. Ahn, Jinyoung Chun, Seo Hui Kang, Kwang Chul Roh, and Sang-Young Lee

Subjects

Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, General Materials Science

Published

2022

2. Form factor-free, printed power sources

Author

David B. Ahn, Kwon Hyung Lee, Seong Sun Lee, Ju Won Lee, Jung Hui Kim, and Sang Young Lee

Subjects

Materials science, Inkwell, Renewable Energy, Sustainability and the Environment, business.industry, Integrated electronics, Electrical engineering, Design diversity, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Energy storage, 0104 chemical sciences, Scalability, General Materials Science, Electronics, 0210 nano-technology, Internet of Things, business, Wearable technology

Abstract

The upcoming ubiquitous electronics era, which will find widespread popularity of flexible/wearable electronics, self-powered devices, and the Internet of Things (IoT), stimulates us to develop a new concept of advanced power sources beyond currently available battery technologies. Among several approaches to reach this goal, printed power sources with various form factors and flexibility have recently garnered considerable attention as a promising system. The form factor-free, printed power sources, driven by their design diversity, shape/performance compatibility with electronics, and scalable/low-cost processability, enable monolithic/seamless integration with complex/unconventional-shaped electronic devices, in comparison to conventional rigid/bulky counterparts. Here, we review the current status and challenges of the form factor-free, printed power sources, with a focus on their materials development. Various printing techniques and their process parameters exploited for the printed power sources are briefly described. Subsequently, ink materials and chemistry of major cell components are discussed. Based on the understanding of the printing techniques and materials, applications of the printed power sources are overviewed to highlight their exceptional shape aesthetics and electrochemical characteristics in the integrated electronics. Finally, we propose development directions and outlook of the form factor-free, printed power sources as a device-customized energy storage system, along with prospects of their future applications.

Published

2020

3. Printed Built-In Power Sources

Author

Ju Won Lee, David B. Ahn, Jung Hui Kim, Sang Young Lee, and Kwon Hyung Lee

Subjects

Inkwell, business.industry, Computer science, Scalability, Electronic engineering, Enabling Factors, Design diversity, Wireless, General Materials Science, Electronics, business, Internet of Things, Interconnectivity

Abstract

Summary The forthcoming smart and ubiquitous electronics era presents significant interest in wireless interconnectivity and shape aesthetics. To fulfill this demand, a new class of advanced power sources with various form factors that are different from existing commercial ones is needed. Printed power sources have recently garnered substantial attention because of their design diversity, shape and performance compatibility with electronics, and scalable and low-cost processability. They are fabricated directly on complex-structured objects via application-customized printing techniques, enabling monolithic integration and electrochemical coupling with target devices. In this Perspective, we describe the current status and challenges of printed power sources, focusing on their role as built-in power sources. Various printing techniques and ink materials and chemistry of electrodes and electrolytes are discussed as key enabling factors. Noteworthy progress in printed built-in power sources is reviewed to highlight their design diversity and electrochemical superiority. Finally, development direction and outlook of printed built-in power sources are discussed in conjunction with their application fields.

Published

2020

4. Printed solid-state electrolytes for form factor-free Li-metal batteries

Author

David B. Ahn, Sang Young Lee, and Kwon-Hyung Lee

Subjects

Solid-state chemistry, Materials science, Fabrication, business.industry, Design diversity, Nanotechnology, Solid state electrolyte, Analytical Chemistry, Form factor (design), Reliability (semiconductor), Hardware_GENERAL, Electrochemistry, Electronics, Internet of Things, business

Abstract

With the ever-growing interests in ubiquitous smart electronics and the Internet of Things, the demand for high-energy-density power sources with aesthetic versatility has increased tremendously. High-energy-density Li-metal batteries have attracted considerable attention for fulfilling the high-energy-density requirement of smart electronics. To obtain form factor-free Li-metal batteries with both design diversity and electrochemical reliability, printed solid-state electrolytes are required as a key component because of their viability for the printing/solidification-based fabrication process and electrode-customized chemical/physical properties. This review present an overview of printed solid-state electrolytes for form factor-free Li-metal batteries with a focus on the materials chemistry and fabrication requirements. In addition, their structural/physical/electrochemical properties were discussed in terms of compatibility with Li-metal batteries.

Published

2022