Namhyung Kim

Scopus Publications

Air and moisture stabilization of layered sodium cathodes through oxygen-affinitive bismuth substitution
Seunghyeop Baek, Yeongkwang Heo, Hyeongseok Lee, Hyeju Kwon, Jangwook Pyun, Gwonsik Nam, Ki Han Kim, Namhyung Kim, Yong Min Lee, Munseok S. Chae
Chemical Engineering Journal, 2026
Amorphous Lithium Borate Coating Enhances the Electrochemical Performance of Lithium Manganese Iron Phosphate Cathodes for Highly Stable Lithium-Ion Batteries
Seunghyeop Baek, Jihun Roh, Jangwook Pyun, Yeon‐U Lee, Sangki Lee, Seung‐Tae Hong, Namhyung Kim, Munseok S. Chae
Batteries and Supercaps, 2025
The advancement of high‐voltage lithium‐ion batteries necessitates the use of cathode materials with improved electrochemical performance and cycling stability. Herein, an amorphous Li2B4O7 coating effectively enhances the electrochemical properties of LiMn0.6Fe0.4PO4 (LMFP) cathodes is demonstrated. Specifically, the Li2B4O7 layer improves lithium‐ion conductivity while suppressing manganese dissolution induced by Jahn‐Teller distortion, both of which are critical factors affecting LMFP stability. Structural and electrochemical analyses reveal that the amorphous coating reduces Coulomb repulsion, lowers the energy barrier for lithium‐ion migration, and enhances charge transfer kinetics. The coated LMFP demonstrates a high discharge capacity of 143.9 mAh g−1 at 20 mA g−1 and exhibits excellent cycling stability, retaining 94.6% of its capacity after 1000 cycles at 600 mA g−1. Furthermore, the amorphous Li2B4O7 coating enhances rate capability by facilitating rapid ion transport. These findings underscore the potential of Li2B4O7 as a multifunctional coating material for advanced lithium‐ion battery cathodes, presenting a scalable and effective strategy for next‐generation energy storage applications.
A surface engineered interlayer of reinforced PP separators for balanced electrochemical and self-extinguishable performance in Li-ion batteries: Morphology and thickness control effects
Min Jeong Lee, Young Je Kwon, Jang Woo Park, Jeongsik Yun, Joonseo Lee, Jagannath Panda, Kaiyun Zhang, Ho Jin Jung, Namhyung Kim, Sujong Chae, Jeong-gu Yeo, Kie Yong Cho
Chemical Engineering Journal, 2025
Synergistic nano-micro structuring boosts high-Ni cathode performance for all-solid-state lithium-ion batteries
Hyungyeon Cha, Hyomyung Lee, Wooyoung Jin, Sujong Chae, Ohjoon Kwon, Jaephil Cho, Namhyung Kim
Energy Storage Materials, 2025
Recent Strategies for Stabilizing Interfaces in All-solid-state Lithium Metal Batteries
Yoon-Jeong Seol, Namhyung Kim
Korean Journal of Chemical Engineering, 2025
Architecting Sturdy Si/Graphite Composite with Lubricative Graphene Nanoplatelets for High-Density Electrodes
Seongsu Park, Minhong Choi, Jinsu Lee, Sangryeol Lee, Jaehyeon Kim, Taeyeong Yun, Namhyung Kim, Jaekyung Sung, Jaephil Cho, Minseong Ko, Sujong Chae
Small, 2025
Densification of the electrode by calendering is essential for achieving high‐energy density in lithium‐ion batteries. However, Si anode, which is regarded as the most promising high‐energy substituent of graphite, is vulnerable to the crack during calendering process due to its intrinsic brittleness. Herein, a distinct strategy to prevent the crack and pulverization of Si nanolayer‐embedded Graphite (Si/G) composite with graphene nanoplatelets (GNP) is proposed. The thickly coated GNP layer on Si/G by simple mechanofusion process imparts exceptional mechanical strength and lubricative characteristic to the Si/G composite, preventing the crack and pulverization of Si nanolayer against strong external force during calendering process. Accordingly, GNP coated Si/G (GNP‐Si/G) composite demonstrates excellent electrochemical performances including superior cycling stability (15.6% higher capacity retention than P‐Si/G after 300 cycles in the full‐cell) and rate capability under the industrial testing condition including high electrode density (>1.6 g cm−3) and high areal capacity (>3.5 mAh cm−2). The material design provides a critical insight for practical approach to resolve the fragile properties of Si/G composite during calendering process.
Unraveling the impact of CNT on electrode expansion in silicon-based lithium-ion batteries
Yujin Kim, Moonjin Kim, Namhyung Kim, Hyungyeon Cha, Seokjin Kim, Jaekyung Sung, Jaephil Cho
Energy Storage Materials, 2025
Identifying the nanostructure of residual Li in high-Ni cathodes for lithium-ion batteries
Wooyoung Jin, Yujin Kim, Haeseong Jang, Yehyeon Gu, Namhyung Kim, Hyomyung Lee, Junhyeok Kim, Sinho Choi, Kyu-Nam Jung, Ki-Hun Nam, Jaephil Cho, Hyungyeon Cha
Journal of Materials Chemistry A, 2024
Identifying the nanostructure of residual Li in high-Ni cathodes is important for their long-term survival. This paper highlights the in-depth understanding of residual Li in nanoscale and suggests appropriate approaches to control the residual Li.
Comparison of commercial silicon-based anode materials for the design of a high-energy lithium-ion battery
Minhong Choi, Eunhan Lee, Jaekyung Sung, Namhyung Kim, Minseong Ko
Nano Research, 2024
Silicon (Si) is considered a potential alternative anode for next-generation Li-ion batteries owing to its high theoretical capacity and abundance. However, the commercial use of Si anodes is hindered by their large volume expansion (∼ 300%). Numerous efforts have been made to address this issue. Among these efforts, Si-graphite co-utilization has attracted attention as a reasonable alternative for high-energy anodes. A comparative study of representative commercial Si-based materials, such as Si nanoparticles, Si suboxides, and Si–Graphite composites (SiGC), was conducted to characterize their overall performance in high-energy lithium-ion battery (LIB) design by incorporating conventional graphite. Nano-Si was found to exhibit poor electrochemical performance, with severe volume expansion during cycling. Si suboxide provided excellent cycling stability in a full-cell evaluation with stable volume variation after 50 cycles, but had a large irreversible capacity and remarkable volume expansion during the first cycle. SiGC displayed a good initial Coulombic efficiency and the lowest volume change in the first cycle owing to the uniformly distributed nano-Si layer on graphite; however, its long-term cycling stability was relatively poor. To complement each disadvantage of Si suboxide and SiGC, a new combination of these Si-based anodes was suggested and a reasonable improvement in overall battery performance was successfully achieved.
Lithium-ion hopping weakens thermal stability of LiPF6 carbonate electrolytes
Kee Sung Han, Mal-Soon Lee, Namhyung Kim, Daiwon Choi, Sujong Chae, Jaegeon Ryu, GiovanniMaria Piccini, Roger Rousseau, Edwin C. Thomsen
Cell Reports Physical Science, 2024
Lithium hexafluorophosphate (LiPF6)-based carbonate electrolytes are widely used in commercial lithium-ion batteries (LIBs), but their thermal instability limits the cycle life and safety of LIBs at elevated temperatures. Few studies have yielded insight into the initial PF6− decomposition reaction that promotes thermal instability of LiPF6-based electrolytes. Here, we find that lithium-ion hopping assisted by the overall reorientational motion of propylene carbonate molecules facilitates PF6− decomposition at elevated temperatures in 1 M LiPF6/propylene carbonate electrolyte. Further, we demonstrate that urea additives, by preventing lithium-ion hopping, suppress the initial LiPF6 decomposition reaction and enhance the thermal stability of the electrolyte. LIB cell tests with LiNi0.6Mn0.2Co0.2O2||Li4Ti5O12 show improved LIB performance at elevated temperatures with the thermally stabilized electrolyte. This study provides key insights into the design of thermally stable LiPF6-based carbonate electrolytes for improving the cycle life, calendar life, and safety of LIBs in elevated-temperature applications.
Suppressing Deformation of Silicon Anodes via Interfacial Synthesis for Fast-Charging Lithium-Ion Batteries
Taeyong Lee, Namhyung Kim, Jiyun Lee, Yoonkwang Lee, Jaekyung Sung, Hyeongjun Kim, Sujong Chae, Hyungyeon Cha, Yeonguk Son, Sang Kyu Kwak, Jaephil Cho
Advanced Energy Materials, 2023
Issues impeding the commercialization of laboratory innovations for energy-dense Si-containing lithium-ion batteries
Namhyung Kim, Yujin Kim, Jaekyung Sung, Jaephil Cho
Nature Energy, 2023
Ball Milling-Enabled Fe2.4+ to Fe3+ Redox Reaction in Prussian Blue Materials for Long-Life Aqueous Sodium-Ion Batteries
Marcos Lucero, Davis B. Armitage, Xin Yang, Sean K. Sandstrom, Mason Lyons, Ryan C. Davis, George E. Sterbinsky, Namhyung Kim, David M. Reed, Xiulei Ji, Xiaolin Li, Zhenxing Feng
ACS Applied Materials and Interfaces, 2023
Carbide-mediated catalytic hydrogenolysis: defects in graphene on a carbonaceous lithium host for liquid and all-solid-state lithium metal batteries
Namhyung Kim, Hyungyeon Cha, Sujong Chae, Taeyong Lee, Yoonkwang Lee, Yujin Kim, Jaekyung Sung, Jaephil Cho
Energy and Environmental Science, 2023
Comparison of Li-ion battery chemistries under grid duty cycles
Namhyung Kim, Nimat Shamim, Alasdair Crawford, Vilayanur V. Viswanathan, Bhuvaneswari M. Sivakumar, Qian Huang, David Reed, Vincent Sprenkle, Daiwon Choi
Journal of Power Sources, 2022
Highly Densified Fracture-Free Silicon-Based Electrode for High Energy Lithium-Ion Batteries
Jaekyung Sung, Namhyung Kim, Sang‐Pil Kim, Taeyong Lee, Moonsu Yoon, Jaephil Cho
Batteries and Supercaps, 2022
Dendrite-free lithium deposition on conventional graphite anode by growth of defective carbon-nanotube for lithium-metal/ion hybrid batteries
Gyuchan Yeo, Jaekyung Sung, Minhong Choi, Namhyung Kim, Minseong Ko
Journal of Materials Chemistry A, 2022
Subnano-sized silicon anode via crystal growth inhibition mechanism and its application in a prototype battery pack
Jaekyung Sung, Namhyung Kim, Jiyoung Ma, Jeong Hyeon Lee, Se Hun Joo, Taeyong Lee, Sujong Chae, Moonsu Yoon, Yoonkwang Lee, Jaeseong Hwang, Sang Kyu Kwak, Jaephil Cho
Nature Energy, 2021
Boosting Reaction Homogeneity in High-Energy Lithium-Ion Battery Cathode Materials
Hyungyeon Cha, Junhyeok Kim, Hyomyung Lee, Namhyung Kim, Jaeseong Hwang, Jaekyung Sung, Moonsu Yoon, Kyungho Kim, Jaephil Cho
Advanced Materials, 2020
Stress Relief Principle of Micron-Sized Anodes with Large Volume Variation for Practical High-Energy Lithium-Ion Batteries
Yoonkwang Lee, Taeyong Lee, Jaehyung Hong, Jaekyung Sung, Namhyung Kim, Yeonguk Son, Jiyoung Ma, Sung Youb Kim, Jaephil Cho
Advanced Functional Materials, 2020
Calendering-Compatible Macroporous Architecture for Silicon–Graphite Composite toward High-Energy Lithium-Ion Batteries
Yeonguk Son, Namhyung Kim, Taeyong Lee, Yoonkwang Lee, Jiyoung Ma, Sujong Chae, Jaekyung Sung, Hyungyeon Cha, Youngshin Yoo, Jaephil Cho
Advanced Materials, 2020
Author Correction: Scalable synthesis of silicon-nanolayer-embedded graphite for high-energy lithium-ion batteries (Nature Energy, (2016), 1, 9, (16113), 10.1038/nenergy.2016.113)
Minseong Ko, Sujong Chae, Jiyoung Ma, Namhyung Kim, Hyun-Wook Lee, Yi Cui, Jaephil Cho
Nature Energy, 2020
Gas phase synthesis of amorphous silicon nitride nanoparticles for high-energy LIBs
Sujong Chae, Seungkyu Park, Kihong Ahn, Gyutae Nam, Taeyong Lee, Jaekyung Sung, Namhyung Kim, Jaephil Cho
Energy and Environmental Science, 2020
Strategic Pore Architecture for Accommodating Volume Change from High Si Content in Lithium-Ion Battery Anodes
Jiyoung Ma, Jaekyung Sung, Yoonkwang Lee, Yeonguk Son, Sujong Chae, Namhyung Kim, Seong‐Hyeon Choi, Jaephil Cho
Advanced Energy Materials, 2020
Integration of Graphite and Silicon Anodes for the Commercialization of High-Energy Lithium-Ion Batteries
Sujong Chae, Seong‐Hyeon Choi, Namhyung Kim, Jaekyung Sung, Jaephil Cho
Angewandte Chemie International Edition, 2020
Towards maximized volumetric capacity via pore-coordinated design for large-volume-change lithium-ion battery anodes
Jiyoung Ma, Jaekyung Sung, Jaehyung Hong, Sujong Chae, Namhyung Kim, Seong-Hyeon Choi, Gyutae Nam, Yoonkook Son, Sung Youb Kim, Minseong Ko, Jaephil Cho
Nature Communications, 2019
Fabrication of Lamellar Nanosphere Structure for Effective Stress-Management in Large-Volume-Variation Anodes of High-Energy Lithium-Ion Batteries
Jaekyung Sung, Jiyoung Ma, Seong‐Hyeon Choi, Jaehyung Hong, Namhyung Kim, Sujong Chae, Yeonguk Son, Sung Youb Kim, Jaephil Cho
Advanced Materials, 2019
Quantification of Pseudocapacitive Contribution in Nanocage-Shaped Silicon–Carbon Composite Anode
Yeonguk Son, Jiyoung Ma, Namhyung Kim, Taeyong Lee, Yoonkwang Lee, Jaekyung Sung, Seong‐Hyeon Choi, Gyutae Nam, Hyeyoung Cho, Youngshin Yoo, Jaephil Cho
Advanced Energy Materials, 2019
Robust Pitch on Silicon Nanolayer–Embedded Graphite for Suppressing Undesirable Volume Expansion
Seong-Hyeon Choi, Gyutae Nam, Sujong Chae, Donghyuk Kim, Namhyung Kim, Won Sik Kim, Jiyoung Ma, Jaekyung Sung, Seung Min Han, Minseong Ko, Hyun-Wook Lee, Jaephil Cho
Advanced Energy Materials, 2019
Fast-charging high-energy lithium-ion batteries via implantation of amorphous silicon nanolayer in edge-plane activated graphite anodes
Namhyung Kim, Sujong Chae, Jiyoung Ma, Minseong Ko, Jaephil Cho
Nature Communications, 2017
One-to-One Comparison of Graphite-Blended Negative Electrodes Using Silicon Nanolayer-Embedded Graphite versus Commercial Benchmarking Materials for High-Energy Lithium-Ion Batteries
Sujong Chae, Namhyung Kim, Jiyoung Ma, Jaephil Cho, Minseong Ko
Advanced Energy Materials, 2017
Critical Role of Cations in Lithium Sites on Extended Electrochemical Reversibility of Co-Rich Layered Oxide
Woongrae Cho, Seungjun Myeong, Namhyung Kim, Sanghan Lee, Youngki Kim, Maengsuk Kim, Seok Ju Kang, Noejung Park, Pilgun Oh, Jaephil Cho
Advanced Materials, 2017
Scalable synthesis of silicon-nanolayer-embedded graphite for high-energy lithium-ion batteries
Minseong Ko, Sujong Chae, Jiyoung Ma, Namhyung Kim, Hyun-Wook Lee, Yi Cui, Jaephil Cho
Nature Energy, 2016
Micron-sized Fe-Cu-Si ternary composite anodes for high energy Li-ion batteries
Sujong Chae, Minseong Ko, Seungkyu Park, Namhyung Kim, Jiyoung Ma, Jaephil Cho
Energy and Environmental Science, 2016

RECENT SCHOLAR PUBLICATIONS

Lithium Extraction via Salt Roasting: Parametric Study and Reaction Mechanism Analysis
Y Heo, YJ Seol, N Kim
249th ECS Meeting (May 24-28, 2026) , 2026
2026
Air and moisture stabilization of layered sodium cathodes through oxygen-affinitive bismuth substitution
S Baek, Y Heo, H Lee, H Kwon, J Pyun, G Nam, KH Kim, N Kim, YM Lee, ...
Chemical Engineering Journal, 176480 , 2026
2026
Amorphous Lithium Borate Coating Enhances the Electrochemical Performance of Lithium Manganese Iron Phosphate Cathodes for Highly Stable Lithium‐Ion Batteries
S Baek, J Roh, J Pyun, YU Lee, S Lee, ST Hong, N Kim, MS Chae
Batteries & Supercaps 8 (12), e202500207 , 2025
2025
Citations: 3
Multi-Scale Design Enables Better Utilization of High-Ni Cathode for All-Solid-State Lithium-Ion Batteries
H Cha, N Kim, J Cho
Electrochemical Society Meeting Abstracts 248, 588-588 , 2025
2025
New Synthesis of Carbonaceous Lithium Hosts for Sulfide-Based All-Solid-State Lithium Metal Batteries
H Cha, N Kim
Electrochemical Society Meeting Abstracts 248, 584-584 , 2025
2025
A surface engineered interlayer of reinforced PP separators for balanced electrochemical and self-extinguishable performance in Li-ion batteries: Morphology and thickness …
MJ Lee, YJ Kwon, JW Park, J Yun, J Lee, J Panda, K Zhang, HJ Jung, ...
Chemical Engineering Journal 520, 165758 , 2025
2025
Citations: 4
Synergistic nano-micro structuring boosts high-Ni cathode performance for all-solid-state lithium-ion batteries
H Cha, H Lee, W Jin, S Chae, O Kwon, J Cho, N Kim
Energy Storage Materials, 104470 , 2025
2025
Citations: 3
Recent Strategies for Stabilizing Interfaces in All-solid-state Lithium Metal Batteries: Y.-J. Seol and N. Kim
YJ Seol, N Kim
Korean Journal of Chemical Engineering 42 (7), 1377-1391 , 2025
2025
Citations: 9
Architecting Sturdy Si/Graphite Composite with Lubricative Graphene Nanoplatelets for High‐Density Electrodes (Small 10/2025)
S Park, M Choi, J Lee, S Lee, J Kim, T Yun, N Kim, J Sung, J Cho, M Ko, ...
Small 21 (10), 2570072 , 2025
2025
Architecting Sturdy Si/Graphite Composite with Lubricative Graphene Nanoplatelets for High‐Density Electrodes
S Park, M Choi, J Lee, S Lee, J Kim, T Yun, N Kim, J Sung, J Cho, M Ko, ...
Small 21 (10), 2404949 , 2025
2025
Citations: 5
Identifying the nanostructure of residual Li in high-Ni cathodes for lithium-ion batteries
W Jin, Y Kim, H Jang, Y Gu, N Kim, H Lee, J Kim, S Choi, KN Jung, ...
Journal of Materials Chemistry A 13 (8), 5599-5605 , 2025
2025
Citations: 9
Unraveling the impact of CNT on electrode expansion in silicon-based lithium-ion batteries
Y Kim, M Kim, N Kim, H Cha, S Kim, J Sung, J Cho
Energy Storage Materials 74, 103983 , 2025
2025
Citations: 31
Comparison of commercial silicon-based anode materials for the design of a high-energy lithium-ion battery
M Choi, E Lee, J Sung, N Kim*, M Ko*
Nano Research, 1-8 , 2024
2024
Citations: 29
Composite anode active material, method of preparing the same, and lithium secondary battery including anode including composite anode active material
JP Cho, YU Son, JY Ma, NH KIM
US Patent 11,901,540 , 2024
2024
Lithium-ion hopping weakens thermal stability of LiPF6 carbonate electrolytes
KS Han, MS Lee, N Kim, D Choi, S Chae, J Ryu, GM Piccini, R Rousseau, ...
Cell Reports Physical Science 5 (1) , 2024
2024
Citations: 28
Cathode material for lithium secondary battery and method of manufacturing the same
SM Oh, IK Kim, YM Yeo, SM Park, YS LEE, NH KIM, JE Lee, DJ Kim, ...
US Patent 11,824,190 , 2023
2023
Negative electrode active material for lithium secondary battery, method for manufacturing the same, and lithium secondary battery comprising the same
JS KIM, JH Lee, NH KIM, JK SUNG, TY Lee, JP Cho
US Patent 11,824,195 , 2023
2023
Citations: 2
Suppressing Deformation of Silicon Anodes via Interfacial Synthesis for Fast‐Charging Lithium‐Ion Batteries
T Lee†, N Kim†, J Lee, Y Lee, J Sung, H Kim, S Chae, H Cha, Y Son, ...
Advanced Energy Materials 13 (41), 2301139 , 2023
2023
Citations: 47
Anode active material for lithium secondary battery, method of preparing the same, and lithium secondary battery containing the same
JH Lee, JS KIM, NH KIM, YU Son, YK LEE, JP Cho
US Patent 11,791,457 , 2023
2023
Issues impeding the commercialization of laboratory innovations for energy-dense Si-containing lithium-ion batteries
N Kim, Y Kim, J Sung, J Cho
Nature Energy 8 (9), 921-933 , 2023
2023
Citations: 281

MOST CITED SCHOLAR PUBLICATIONS

Integration of graphite and silicon anodes for the commercialization of high‐energy lithium‐ion batteries
S Chae, SH Choi, N Kim, J Sung, J Cho
Angewandte Chemie International Edition 59 (1), 110-135 , 2020
2020
Citations: 904
Scalable synthesis of silicon-nanolayer-embedded graphite for high-energy lithium-ion batteries
M Ko, S Chae, J Ma, N Kim, HW Lee, Y Cui, J Cho
Nature Energy 1 (9), 1-8 , 2016
2016
Citations: 824
Fast-charging high-energy lithium-ion batteries via implantation of amorphous silicon nanolayer in edge-plane activated graphite anodes
N Kim, S Chae, J Ma, M Ko, J Cho
Nature communications 8 (1), 812 , 2017
2017
Citations: 488
Subnano-sized silicon anode via crystal growth inhibition mechanism and its application in a prototype battery pack
J Sung†, N Kim†, J Ma, JH Lee, SH Joo, T Lee, S Chae, M Yoon, Y Lee, ...
Nature Energy, 1-12 , 2021
2021
Citations: 282
Issues impeding the commercialization of laboratory innovations for energy-dense Si-containing lithium-ion batteries
N Kim, Y Kim, J Sung, J Cho
Nature Energy 8 (9), 921-933 , 2023
2023
Citations: 281
Boosting reaction homogeneity in high‐energy lithium‐ion battery cathode materials
H Cha, J Kim, H Lee, N Kim, J Hwang, J Sung, M Yoon, K Kim, J Cho
Advanced Materials 32 (39), 2003040 , 2020
2020
Citations: 219
Calendering‐Compatible Macroporous Architecture for Silicon–Graphite Composite toward High‐Energy Lithium‐Ion Batteries
Y Son†, N Kim†, T Lee, Y Lee, J Ma, S Chae, J Sung, H Cha, Y Yoo, ...
Advanced Materials, 2003286 , 2020
2020
Citations: 195
Robust pitch on silicon nanolayer–embedded graphite for suppressing undesirable volume expansion
SH Choi, G Nam, S Chae, D Kim, N Kim, WS Kim, J Ma, J Sung, SM Han, ...
Advanced Energy Materials 9 (4), 1803121 , 2019
2019
Citations: 190
Micron-sized Fe–Cu–Si ternary composite anodes for high energy Li-ion batteries
S Chae, M Ko, S Park, N Kim, J Ma, J Cho
Energy & Environmental Science 9 (4), 1251-1257 , 2016
2016
Citations: 188
Towards maximized volumetric capacity via pore-coordinated design for large-volume-change lithium-ion battery anodes
J Ma, J Sung, J Hong, S Chae, N Kim, SH Choi, G Nam, Y Son, SY Kim, ...
Nature Communications 10 (1), 475 , 2019
2019
Citations: 152
One‐to‐One Comparison of Graphite‐Blended Negative Electrodes Using Silicon Nanolayer‐Embedded Graphite versus Commercial Benchmarking Materials for High‐Energy Lithium‐Ion …
S Chae†, N Kim†, J Ma, J Cho, M Ko
Advanced Energy Materials 7 (15), 1700071 , 2017
2017
Citations: 140
Quantification of pseudocapacitive contribution in nanocage‐shaped silicon–carbon composite anode
Y Son, J Ma, N Kim, T Lee, Y Lee, J Sung, SH Choi, G Nam, H Cho, Y Yoo, ...
Advanced Energy Materials 9 (11), 1803480 , 2019
2019
Citations: 112
Strategic pore architecture for accommodating volume change from high Si content in lithium‐ion battery anodes
J Ma, J Sung, Y Lee, Y Son, S Chae, N Kim, SH Choi, J Cho
Advanced Energy Materials 10 (6), 1903400 , 2020
2020
Citations: 108
Gas phase synthesis of amorphous silicon nitride nanoparticles for high-energy LIBs
S Chae, S Park, K Ahn, G Nam, T Lee, J Sung, N Kim, J Cho
Energy & Environmental Science 13 (4), 1212-1221 , 2020
2020
Citations: 87
Critical role of cations in lithium sites on extended electrochemical reversibility of co‐rich layered oxide
W Cho, S Myeong, N Kim, S Lee, Y Kim, M Kim, SJ Kang, N Park, P Oh, ...
Advanced Materials 29 (21), 1605578 , 2017
2017
Citations: 80
Fabrication of Lamellar Nanosphere Structure for Effective Stress‐Management in Large‐Volume‐Variation Anodes of High‐Energy Lithium‐Ion Batteries
J Sung, J Ma, SH Choi, J Hong, N Kim, S Chae, Y Son, SY Kim, J Cho
Advanced Materials 31 (33), 1900970 , 2019
2019
Citations: 77
Stress relief principle of micron‐sized anodes with large volume variation for practical high‐energy lithium‐ion batteries
Y Lee, T Lee, J Hong, J Sung, N Kim, Y Son, J Ma, SY Kim, J Cho
Advanced Functional Materials 30 (40), 2004841 , 2020
2020
Citations: 67
Suppressing Deformation of Silicon Anodes via Interfacial Synthesis for Fast‐Charging Lithium‐Ion Batteries
T Lee†, N Kim†, J Lee, Y Lee, J Sung, H Kim, S Chae, H Cha, Y Son, ...
Advanced Energy Materials 13 (41), 2301139 , 2023
2023
Citations: 47
Comparison of Li-ion battery chemistries under grid duty cycles
N Kim, N Shamim, A Crawford, VV Viswanathan, BM Sivakumar, Q Huang, ...
Journal of Power Sources 546, 231949 , 2022
2022
Citations: 46
Unraveling the impact of CNT on electrode expansion in silicon-based lithium-ion batteries
Y Kim, M Kim, N Kim, H Cha, S Kim, J Sung, J Cho
Energy Storage Materials 74, 103983 , 2025
2025
Citations: 31

Namhyung Kim

RESEARCH, TEACHING, or OTHER INTERESTS

Scopus Publications

RECENT SCHOLAR PUBLICATIONS

MOST CITED SCHOLAR PUBLICATIONS