Access the full text.
Sign up today, get DeepDyve free for 14 days.
Minseong Ko, Sujong Chae, Sookyung Jeong, Pilgun Oh, Jaephil Cho (2014)
Elastic a-silicon nanoparticle backboned graphene hybrid as a self-compacting anode for high-rate lithium ion batteries.ACS nano, 8 8
Minseong Ko, Sujong Chae, Jiyoung Ma, Namhyung Kim, Hyun‐Wook Lee, Yi Cui, Jaephil Cho (2016)
Scalable synthesis of silicon-nanolayer-embedded graphite for high-energy lithium-ion batteriesNature Energy, 1
Candace Chan, H. Peng, Gao Liu, K. Mcilwrath, Xiao Zhang, R. Huggins, Yi Cui (2008)
High-performance lithium battery anodes using silicon nanowires.Nature nanotechnology, 3 1
Nian Liu, Zhenda Lu, Jie Zhao, M. McDowell, Hyun‐Wook Lee, Wenting Zhao, Yi Cui (2014)
A pomegranate-inspired nanoscale design for large-volume-change lithium battery anodes.Nature nanotechnology, 9 3
M. Lukatskaya, B. Dunn, Y. Gogotsi (2016)
Multidimensional materials and device architectures for future hybrid energy storageNature Communications, 7
Mater
Hui Wu, Gerentt Chan, J. Choi, I. Ryu, Yan Yao, M. McDowell, S. Lee, A. Jackson, Yuan Yang, Liangbing Hu, Yi Cui (2012)
Stable cycling of double-walled silicon nanotube battery anodes through solid-electrolyte interphase control.Nature nanotechnology, 7 5
Yinzhu Jiang, Yong Li, Peng Zhou, Zhenyun Lan, Yunhao Lu, Chen Wu, M. Yan (2017)
Ultrafast, Highly Reversible, and Cycle‐Stable Lithium Storage Boosted by Pseudocapacitance in Sn‐Based Alloying AnodesAdvanced Materials, 29
K. Evanoff, A. Magasinski, Junbing Yang, G. Yushin (2011)
Nanosilicon‐Coated Graphene Granules as Anodes for Li‐Ion BatteriesAdvanced Energy Materials, 1
W. Ren, Zailei Zhang, Yanhong Wang, Qiangqiang Tan, Z. Zhong, F. Su (2015)
Preparation of porous silicon/carbon microspheres as high performance anode materials for lithium ion batteriesJournal of Materials Chemistry, 3
T. Yuan, Yinzhu Jiang, Qiuting Wang, Bin Pan, M. Yan (2017)
Pseudocapacitance‐Enhanced High‐Rate Lithium Storage in “Honeycomb”‐like Mn2O3 Anodes, 4
Zhenda Lu, Nian Liu, Hyun‐Wook Lee, Jie Zhao, Weiyang Li, Yuzhang Li, Yi Cui (2015)
Nonfilling carbon coating of porous silicon micrometer-sized particles for high-performance lithium battery anodes.ACS nano, 9 3
T.-C. Liu, W. Pell, B. Conway, S. Roberson (1998)
Behavior of Molybdenum Nitrides as Materials for Electrochemical Capacitors Comparison with Ruthenium OxideJournal of The Electrochemical Society, 145
M. Lukatskaya, O. Mashtalir, Chang Ren, Yohan Dall’Agnese, P. Rozier, P. Taberna, Michael Naguib, P. Simon, M. Barsoum, Y. Gogotsi (2013)
Cation Intercalation and High Volumetric Capacitance of Two-Dimensional Titanium CarbideScience, 341
Jim Zheng, P. Cygan, T. Jow (1995)
Hydrous Ruthenium Oxide as an Electrode Material for Electrochemical CapacitorsJournal of The Electrochemical Society, 142
(2015)
Wohlfahrt-Mehrens, Electrochim
Sujong Chae, Minseong Ko, Kyung-Ho Kim, Kihong Ahn, Jaephil Cho (2017)
Confronting Issues of the Practical Implementation of Si Anode in High-Energy Lithium-Ion BatteriesJoule, 1
T. Waldmann, M. Kasper, M. Wohlfahrt‐Mehrens (2015)
Optimization of Charging Strategy by Prevention of Lithium Deposition on Anodes in high-energy Lithium-ion Batteries – Electrochemical ExperimentsElectrochimica Acta, 178
Hyejung Kim, M. Seo, Mi-hee Park, Jaephil Cho (2010)
A critical size of silicon nano-anodes for lithium rechargeable batteries.Angewandte Chemie, 49 12
M. Stournara, R. Kumar, Y. Qi, B. Sheldon (2016)
Ab initio diffuse-interface model for lithiated electrode interface evolution.Physical review. E, 94 1-1
Hui Wu, Yi Cui (2012)
Designing nanostructured Si anodes for high energy lithium ion batteriesNano Today, 7
Yong-seok Choi, Young-Woon Byeon, Jae-pyoung Ahn, Jae‐Chul Lee (2017)
Formation of Zintl Ions and Their Configurational Change during Sodiation in Na-Sn Battery.Nano letters, 17 2
Ouassim Ghodbane, J. Pascal, F. Favier (2008)
Microstructural effects on charge-storage properties in MnO2-based electrochemical supercapacitors.ACS applied materials & interfaces, 1 5
Mi-hee Park, Min Kim, J. Joo, Kitae Kim, Jeyoung Kim, Soonho Ahn, Yi Cui, Jaephil Cho (2009)
Silicon nanotube battery anodes.Nano letters, 9 11
Zailei Zhang, Yanhong Wang, W. Ren, Qiangqiang Tan, Yunfa Chen, Hong Li, Z. Zhong, F. Su (2014)
Scalable synthesis of interconnected porous silicon/carbon composites by the Rochow reaction as high-performance anodes of lithium ion batteries.Angewandte Chemie, 53 20
V. Augustyn, J. Come, Michael Lowe, J. Kim, P. Taberna, S. Tolbert, H. Abruña, P. Simon, B. Dunn (2013)
High-rate electrochemical energy storage through Li+ intercalation pseudocapacitance.Nature materials, 12 6
In-Hyuk Son, J. Park, Seongyong Park, Kwangjin Park, Sangil Han, Jaeho Shin, S. Doo, Y. Hwang, Hyuk Chang, J. Choi (2017)
Graphene balls for lithium rechargeable batteries with fast charging and high volumetric energy densitiesNature Communications, 8
Liangdong Lin, Xuena Xu, Chenxiao Chu, M. Majeed, Jian Yang (2016)
Mesoporous Amorphous Silicon: A Simple Synthesis of a High-Rate and Long-Life Anode Material for Lithium-Ion Batteries.Angewandte Chemie, 55 45
Benjamin Lesel, Jesse Ko, B. Dunn, S. Tolbert (2016)
Mesoporous LixMn2O4 Thin Film Cathodes for Lithium-Ion Pseudocapacitors.ACS nano, 10 8
Ran Yi, Fang Dai, Mikhail Gordin, H. Sohn, Donghai Wang (2013)
Influence of Silicon Nanoscale Building Blocks Size and Carbon Coating on the Performance of Micro‐Sized Si–C Composite Li‐Ion AnodesAdvanced Energy Materials, 3
Sujong Chae, Minseong Ko, Seungkyu Park, Namhyung Kim, Jiyoung Ma, Jaephil Cho (2016)
Micron-sized Fe–Cu–Si ternary composite anodes for high energy Li-ion batteriesEnergy and Environmental Science, 9
A. Magasinski, P. Dixon, B. Hertzberg, A. Kvit, J. Ayala, G. Yushin (2010)
High-performance lithium-ion anodes using a hierarchical bottom-up approach.Nature materials, 9 4
In-Hyuk Son, Jong Park, Soonchul Kwon, Seongyong Park, M. Rümmeli, A. Bachmatiuk, H. Song, J. Ku, J. Choi, Jae-man Choi, S. Doo, Hyuk Chang (2015)
Silicon carbide-free graphene growth on silicon for lithium-ion battery with high volumetric energy densityNature Communications, 6
Y. Gogotsi, R. Penner (2018)
Energy Storage in Nanomaterials - Capacitive, Pseudocapacitive, or Battery-like?ACS nano, 12 3
Namhyung Kim, Sujong Chae, Jiyoung Ma, Minseong Ko, Jaephil Cho (2017)
Fast-charging high-energy lithium-ion batteries via implantation of amorphous silicon nanolayer in edge-plane activated graphite anodesNature Communications, 8
Jie Zhao, Hyun‐Wook Lee, Jie Sun, Kai Yan, Yayuan Liu, Wei Liu, Zhenda Lu, Dingchang Lin, Guangmin Zhou, Yi Cui (2016)
Metallurgically lithiated SiOx anode with high capacity and ambient air compatibilityProceedings of the National Academy of Sciences, 113
Yeonguk Son, Jaekyung Sung, Yoonkook Son, Jaephil Cho (2017)
Recent progress of analysis techniques for silicon-based anode of lithium-ion batteriesCurrent Opinion in Electrochemistry, 6
E. Buiel, J. Dahn (1999)
Li-insertion in hard carbon anode materials for Li-ion batteriesElectrochimica Acta, 45
Xu Quan, Jiankun Sun, Jin‐Yi Li, Ya‐Xia Yin, Yu‐Guo Guo (2018)
Scalable synthesis of spherical Si/C granules with 3D conducting networks as ultrahigh loading anodes in lithium-ion batteriesEnergy Storage Materials, 12
Quan Xu, Jin‐Yi Li, Jiankun Sun, Ya‐Xia Yin, L. Wan, Yu‐Guo Guo (2017)
Watermelon‐Inspired Si/C Microspheres with Hierarchical Buffer Structures for Densely Compacted Lithium‐Ion Battery AnodesAdvanced Energy Materials, 7
V. Augustyn, P. Simon, B. Dunn (2014)
Pseudocapacitive oxide materials for high-rate electrochemical energy storageEnergy and Environmental Science, 7
John Wang, J. Polleux, James Lim, B. Dunn (2007)
Pseudocapacitive Contributions to Electrochemical Energy Storage in TiO2 (Anatase) NanoparticlesJournal of Physical Chemistry C, 111
Pseudocapacitive materials have been highlighted as promising electrode materials to overcome slow diffusion‐limited redox mechanism in active materials, which impedes fast charging/discharging in energy storage devices. However, previously reported pseudocapacitive properties have been rarely used in lithium‐ion batteries (LIBs) and evaluation methods have been limited to those focused on thin‐film‐type electrodes. Hence, a nanocage‐shaped silicon–carbon composite anode is proposed with excellent pseudocapacitive qualities for LIB applications. This composite anode exhibits a superior rate capability compared to other Si‐based anodes, including commercial silicon nanoparticles, because of the higher pseudocapacitive contribution coming from ultrathin Si layer. Furthermore, unprecedent 3D pore design in cage shape, which prevents the particle scale expansion even after full lithiation demonstrates the high cycling stability. This concept can potentially be used to realize high‐power and high‐energy LIB anode materials.
Advanced Energy Materials – Wiley
Published: Mar 1, 2019
Keywords: ; ; ;
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.