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[세미나: 7월 14일(금), 오후 3시] Prof. Jinhyuk Lee, McGill University

Title

Opportunities and challenges of practical high-energy disordered rock-salt Li-ion cathodes

Speaker

Prof. Jinhyuk Lee, McGill University

Biography

Dr. Jinhyuk Lee is an Assistant Professor of Materials Engineering and a William Dawson 

Scholar (Distinguished Professorship) at McGill University. He received his B.Sc. and Ph.D. 

in Materials Science and Engineering from Seoul National University (2010) and MIT (2015). 

Before joining McGill in 2020, Dr. Lee performed postdoctoral research at UC Berkeley 

(2016–2017) and MIT (2017–2019). His research interest is discovering sustainable battery 

materials based on experimental and theoretical materials research. He was a finalist of the 

Science Award Electrochemistry 2019 by Volkswagen–BASF and is a 2020 recipient of the 

NSERC Discovery Accelerator Supplement. He has made critical contributions to developing 

high-energy cathode materials for Li-ion batteries, leading to his publications in top journals, 

including Science (2014), Nature (2018), Nature Chemistry (2016), Joule (2022), and Adv. 

Mater. (2023). He currently leads the JINfinity Energy Lab at McGill University and is a 

Scientific Advisor of Neo Battery Materials Ltd. in Canada

| Date | Friday, July 14th, 2023

| Time | 15:00 ~ 

| Venue | 33동 125호 (WCU 다목적실) 

[Abstract]

Ni/Co-free cathode materials with a high energy density can lead to sustainable, low-cost Liion batteries (LIBs) that satisfy the ever-increasing demand for electrical energy storage for 

electric vehicles and large-scale renewable-energy storage. By delivering higher energy density 

(>900 Wh/kg) than the layered oxides (~770 Wh/kg) with the affordability of LiFePO4 (a cheap 

albeit low energy-density cathode, ~580 Wh/kg), disordered rock-salts (DRXs, e.g., Li2MnO2F, 

Li2Mn1/2Ti1/2O2F, and Li1.68Mn1.60O3.7F0.3) made of cheaper metals (Mn, Ti, etc.) than Ni and 

Co are one of only a handful of Co/Ni-free cathode materials with one of the lowest projected 

cost per energy-stored ($/Wh), that can shift the current cathode market-share. However, there 

are critical challenges for the materials to bring a practical impact on LIB development, such 

as large voltage swings, limited capacity retention, and a lack of scalable material synthesis 

methods. In this talk, by going through the literature and fundamentals of battery material 

design, I will lay out the design principles and challenges of constructing practical Ni/Co-free

DRXs cathode materials for advanced LIBs

| Host | 강기석 교수(02-880-7088)