Promoting Si-graphite composite anodes with SWCNT additives for half and NCM811 full lithium ion batteries and assessment criteria from an industrial perspective
Received date: 26 May 2019
Accepted date: 21 Aug 2019
Published date: 15 Dec 2019
Copyright
Single wall carbon nanotube (SWCNT) additives were formulated into µm-Si-graphite composite electrodes and tested in both half cells and full cells with high nickel cathodes. The critical role of small amount of SWCNT addition (0.2 wt%) was found for significantly improving delithiation capacity, first cycle coulombic efficiency (FCE), and capacity retention. Particularly, Si (10 wt%)-graphite electrode exhibits 560 mAh/g delithiation capacity and 92% FCE at 0.2 C during the first charge-discharge cycle, and 91% capacity retention after 50 cycles (0.5 C) in a half cell. Scanning electron microscope (SEM) was used to illustrate the electrode morphology, compositions and promoting function of the SWCNT additives. In addition, full cells assembled with high nickel-NCM811 cathodes and µm-Si-graphite composite anodes were evaluated for the consistence between half and full cell performance, and the consideration for potential commercial application. Finally, criteria to assess Si-containing anodes are proposed and discussed from an industrial perspective.
Jingning SHAN , Xiaofang YANG , Chao YAN , Lin CHEN , Fang ZHAO , Yiguang JU . Promoting Si-graphite composite anodes with SWCNT additives for half and NCM811 full lithium ion batteries and assessment criteria from an industrial perspective[J]. Frontiers in Energy, 2019 , 13(4) : 626 -635 . DOI: 10.1007/s11708-019-0650-y
1 |
Tarascon J M, Armand M. Issues and challenges facing rechargeable lithium batteries. Nature, 2001, 414(6861): 359–367
|
2 |
Dunn B, Kamath H, Tarascon J M. Electrical energy storage for the grid: a battery of choices. Science, 2011, 334(6058): 928–935
|
3 |
Ellis B L, Lee K T, Nazar L F. Positive electrode materials for Li-ion and Li-batteries. Chemistry of Materials, 2010, 22(3): 691–714
|
4 |
Etacheri V, Marom R, Elazari R, Salitra G, Aurbach D. Challenges in the development of advanced Li-ion batteries: a review. Energy & Environmental Science, 2011, 4(9): 3243–3262
|
5 |
Goodenough J B, Kim Y. Challenges for rechargeable Li batteries. Chemistry of Materials, 2010, 22(3): 587–603
|
6 |
Goriparti S, Miele E, De Angelis F, Di Fabrizio E, Proietti Zaccaria R, Capiglia C. Review on recent progress of nanostructured anode materials for Li-ion batteries. Journal of Power Sources, 2014, 257: 421–443
|
7 |
Su X, Wu Q L, Li J C, Xiao X, Lott A, Lu W, Sheldon B W, Wu J. Silicon-based nanomaterials for lithium-ion batteries: a review. Advanced Energy Materials, 2014, 4(1): 1300882
|
8 |
Jin Y, Zhu B, Lu Z D, Liu N, Zhu J. Challenges and recent progress in the development of Si anodes for lithium-ion battery. Advanced Energy Materials, 2017, 7(23): 1700715
|
9 |
Qian J F, Henderson W A, Xu W, Bhattacharya P, Engelhard M, Borodin O, Zhang J G. High rate and stable cycling of lithium metal anode. Nature Communications, 2015, 6(1): 6362
|
10 |
Zheng G Y, Lee S W, Liang Z, Lee H W, Yan K, Yao H, Wang H, Li W, Chu S, Cui Y. Interconnected hollow carbon nanospheres for stable lithium metal anodes. Nature Nanotechnology, 2014, 9(8): 618–623
|
11 |
Yang S F, Zavalij P Y, Whittingham M S. Anodes for lithium batteries: tin revisited. Electrochemistry Communications, 2003, 5(7): 587–590
|
12 |
Chan C K, Peng H, Liu G, McIlwrath K, Zhang X F, Huggins R A, Cui Y. High-performance lithium battery anodes using silicon nanowires. Nature Nanotechnology, 2008, 3(1): 31–35
|
13 |
Liu X H, Huang J Y. In situ TEM electrochemistry of anode materials in lithium ion batteries. Energy & Environmental Science, 2011, 4(10): 3844–3860
|
14 |
Li J, Dahn J R. An in situ X-ray diffraction study of the reaction of Li with crystalline Si. Journal of the Electrochemical Society, 2007, 154(3): A156–A161
|
15 |
Szczech J R, Jin S. Nanostructured silicon for high capacity lithium battery anodes. Energy & Environmental Science, 2011, 4(1): 56–72
|
16 |
Li Y Z, Yan K, Lee H W, Lu Z, Liu N, Cui Y. Growth of conformal graphene cages on micrometre-sized silicon particles as stable battery anodes. Nature Energy, 2016, 1(2): 15029
|
17 |
Kim H S, Chung K Y, Cho L W. Effect of carbon-coated silicon/graphite composite anode on the electrochemical properties. Bulletin of the Korean Chemical Society, 2008, 29(10): 1965–1968
|
18 |
Liu N, Wu H, McDowell M T, Yao Y, Wang C, Cui Y. A yolk-shell design for stabilized and scalable Li-ion battery alloy anodes. Nano Letters, 2012, 12(6): 3315–3321
|
19 |
Zong L Q, Jin Y, Liu C, Zhu B, Hu X, Lu Z, Zhu J. Precise perforation and scalable production of Si particles from low-grade sources for high-performance lithium ion battery anodes. Nano Letters, 2016, 16(11): 7210–7215
|
20 |
Sohn M, Lee D G, Park H I, Park C, Choi J H, Kim H. Microstructure controlled porous silicon particles as a high capacity lithium storage material via dual step pore engineering. Advanced Functional Materials, 2018, 28(23): 1800855
|
21 |
Obrovac M N. Si-alloy negative electrodes for Li-ion batteries. Current Opinion in Electrochemstry, 2018, 9: 8–17
|
22 |
Huang X D, Gan X F, Zhang F, Huang Q A, Yang J Z. Improved electrochemical performance of silicon nitride film by hydrogen incorporation for lithium-ion battery anode. Electrochimica Acta, 2018, 268: 241–247
|
23 |
Lu W Q, Zhang L H, Qin Y, Jansen A. Calendar and cycle life of lithium-ion batteries containing silicon monoxide anode. Journal of the Electrochemical Society, 2018, 165(10): A2179–A2183
|
24 |
Su M R, Wang Z, Guo H, Li X, Huang S, Xiao W, Gan L. Enhancement of the cyclability of a Si/Graphite@Graphene composite as anode for Lithium-ion batteries. Electrochimica Acta, 2014, 116: 230–236
|
25 |
Gan L, Guo H, Wang Z, Li X, Peng W, Wang J, Huang S, Su M. A facile synthesis of graphite/silicon/graphene spherical composite anode for lithium-ion batteries. Electrochimica Acta, 2013, 104: 117–123
|
26 |
Yim C H, Courtel F M, Abu-Lebdeh Y. A high capacity silicon-graphite composite as anode for lithium-ion batteries using low content amorphous silicon and compatible binders. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2013, 1(28): 8234–8243
|
27 |
Khomenko V G, Barsukov V Z, Doninger J E, Barsukov I V. Lithium-ion batteries based on carbon-silicon-graphite composite anodes. Journal of Power Sources, 2007, 165(2): 598–608
|
28 |
Wang W, Kumta P N. Reversible high capacity nanocomposite anodes of Si/C/SWNTs for rechargeable Li-ion batteries. Journal of Power Sources, 2007, 172(2): 650–658
|
29 |
Jo Y N, Kim Y, Kim J S, Song J H, Kim K J, Kwag C Y, Lee D J, Park C W, Kim Y J. Si-graphite composites as anode materials for lithium secondary batteries. Journal of Power Sources, 2010, 195(18): 6031–6036
|
30 |
Zhao J, Lu Z, Liu N, Lee H W, McDowell M T, Cui Y. Dry-air-stable lithium silicide-lithium oxide core-shell nanoparticles as high-capacity prelithiation reagents. Nature Communications, 2014, 5(1): 5088
|
31 |
Kim H J, Choi S, Lee S J, Seo M W, Lee J G, Deniz E, Lee Y J, Kim E K, Choi J W. Controlled prelithiation of silicon monoxide for high performance lithium-ion rechargeable full cells. Nano Letters, 2016, 16(1): 282–288
|
32 |
Liang B, Liu Y P, Xu Y H. Silicon-based materials as high capacity anodes for next generation lithium ion batteries. Journal of Power Sources, 2014, 267: 469–490
|
33 |
Andre D, Kim S J, Lamp P, Lux S F, Maglia F, Paschos O, Stiaszny B. Future generations of cathode materials: an automotive industry perspective. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2015, 3(13): 6709–6732
|
34 |
Liu X H, Zhong L, Huang S, Mao S X, Zhu T, Huang J Y. Size-dependent fracture of silicon nanoparticles during lithiation. ACS Nano, 2012, 6(2): 1522–1531
|
35 |
de las Casas C, Li W. Li W Z. A review of application of carbon nanotubes for lithium ion battery anode material. Journal of Power Sources, 2012, 208: 74–85
|
36 |
Zhang J, Liang Y H, Zhou Q, Peng Y, Yang H B. Enhancing electrochemical properties of silicon-graphite anodes by the introduction of cobalt for lithium-ion batteries. Journal of Power Sources, 2015, 290: 71–79
|
37 |
Klett M, Gilbert J A, Pupek K Z, Trask S E, Abraham D P. Layered oxide, graphite and silicon-graphite electrodes for lithium-ion cells: effect of electrolyte composition and cycling windows. Journal of the Electrochemical Society, 2017, 164(1): A6095–A6102
|
38 |
Charged Electric Vehicles Magazine. Solving the energy density challenge with single wall carbon. 2017, available at chargedevs.com website
|
39 |
Dash R, Pannala S. Theoretical limits of energy density in silicon-carbon composite anode based lithium ion batteries. Scientific Reports, 2016, 6(1): 27449
|
40 |
Abram C, Shan J, Yang X, Yan C, Steingart D, Ju Y. Flame aerosol synthesis and electrochemical characterisation of Ni-rich layered cathode materials for Li-ion batteries. ACS Applied Energy Materials, 2019, 2(2): 1319–1329
|
41 |
Sun A T, Zhong H, Zhou X, Tang J, Jia M, Cheng F, Wang Q, Yang J. Scalable synthesis of carbon-encapsulated nano-Si on graphite anode material with high cyclic stability for lithium-ion batteries. Applied Surface Science, 2019, 470: 454–461
|
42 |
Fang G, Deng X L, Zou J Z, Zeng X. Amorphous/ordered dual carbon coated silicon nanoparticles as anode to enhance cycle performance in lithium ion batteries. Electrochimica Acta, 2019, 295: 498–506
|
43 |
Sui D, Xie Y, Zhao W, Zhang H, Zhou Y, Qin X, Ma Y, Yang Y, Chen Y. A high-performance ternary Si composite anode material with crystal graphite core and amorphous carbon shell. Journal of Power Sources, 2018, 384: 328–333
|
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