Korea University


QS Subject Rankings 26 areas Entered the top 100

QS World University  Rankings 2023 74th


now page


게시판 -- 목록(갤러리)
Thick cathode technology developed for next-generation high-perf...
  • 글쓴이 : Communications Team
  • 조회 : 317
  • 일 자 : 2024-01-30

Thick cathode technology developed for next-generation high-performance lithium metal secondary batteries

Study by Prof. Yun Young-soo’s team published in international journal Advanced Fiber Materials



(왼쪽부터) 윤영수 교수(교신저자, 고려대 KU-KIST융합대학원), 강동혁(제1저자, 고려대 석박통합과정), 박민혁(공동 제1저자, 고려대 석박통합과정), 이정훈(공동 제1저자, 고려대 연구교수)

▲ (From left) Professor Yun Young-soo (corresponding author, KU-KIST Graduate School of Converging Science and Technology), Kang Dong-hyuk (first author, integrated master-doctoral degree program),  

Park Min-hyuck (co-first author, integrated master-doctoral degree program), Lee Jeong-hun (co-first author, research professor)



The research team led by Professor Yun Young-soo from the Department of Integrative Energy Engineering has developed a thick cathode technology to increase the energy density of lithium metal secondary batteries.

The results of this study were published online on December 12, 2023, in the international journal Advanced Fiber Materials (IF: 16.1, top 1.7%).
* Title of paper: High-Performance Thick Cathode Based on Polyhydroxyalkanoate Binder for Li Metal Batteries.

The thick cathode technology aimed at increasing the electrode density of lithium secondary batteries overcomes the energy limitations without altering the conventional cathode materials used in lithium secondary batteries. However, the typical slurry method used in electrode manufacturing poses challenges such as cracking and flaking during the production of thick electrodes. Additionally, it leads to increased charge transfer resistance and local current overload, resulting in severe technical limitations such as a compromised rate capability and poor cycling stability.

In this study, a high-performance thick electrode was manufactured using a dual-network combination strategy based on a conductive nanofibrillar network (CNN) and a nano-bridging amorphous polyhydroxyalkanoate (aPHA) binder. The CNN and aPHA dual network demonstrated ease of thick cathode manufacture (≥250 μm thickness and ≥90 wt.% active cathode material) through a mass-producible slurry method, while exhibiting a high rate capability and excellent cycling stability.

Furthermore, the combination of the thick cathode and thin Li metal anode pair (Li//t-NCM) demonstrated optimal energy performance, providing a high-performance lithium metal battery with a high energy density of ~25.3 mW cm−2, an output density of ~1,720 W L−1, and an outstanding specific energy of ~470 W h kg−1 at 6 mA h cm−2.




<Figure 1>

이중 네트워크 조합 전략을 이용한 후막 전극의 모식도 및 도전재와 바인더의 기능적 역할을 비교하기 위한 다이어그램

▲ Figure description : Schematic of the thick electrode created using the dual-network combination strategy, and a diagram comparing the functional roles of the conductive network and binder

Research 게시판 리스트