| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
|
|
|
|
|
| Progress on the Carbonate-based Electrolyte Designed for Lithium-ion Batteries with Wide Operating Temperature Range |
| PU Wenjing1,2, LU Wei1, XIE Kai3, ZHENG Chunman3
|
1 Institutes of Physical Science and Information Technology, Anhui University, Hefei 230601, China;
2 Institute of Applied Physics, Army Academy of Artillery & Air Defense, Hefei 230031, China;
3 Institute of College of Aerospace Science and Engineering, National University of Defense Technology, Changsha 410073, China |
|
|
|
Abstract Today the application of lithium-ion batteries (LIBs) is significantly limited by the operating temperature range. The operating temperature required for consumer electronic devices is usually -20—60 ℃, which is basically consistent with operating temperature of the available conventional lithium ion batteries. To adapt to regional and seasonal temperature differences of electric vehicles/hybrid electric vehicle, LIBs are idea-lly required to show high energy density similar to that at room temperature and maintain an excellent cycling performance from -30—70 ℃. To enhance the survival ability and adaptability, LIBs for certain military and space applications need much stricter requirement on wide temperature range. Especially, the low temperature limit should be lower than -50 ℃. Available LIBs are obviously difficult to work in such a wide temperature range for a long time, so LIBs with wide operating temperature have been attracted more attention in recent years.
Wide operating properties should be simultaneously considered at both low and elevated temperature. The main problem at low temperature is the diffusion of lithium ion, which is a reversible process but does not cause significant damage to the composition and structure of original batte-ry. However, the main problems of elevated temperature are the decomposition of electrolyte and the chemical passivation loss of interfaces between electrolyte and positive / negative electrode. The irreversible process leads to the rapid decrease of discharge capacity and cycling perfor-mance.
At present, electrolyte optimization is the most feasible and economical way to broaden the operating temperature range. The design and pro-perties studies of wide temperature electrolyte involve three aspects: the solvation of electrolyte, the surface chemical reaction between electrolyte and negative electrode, and the interface reaction on positive electrode. Liquid phase of electrolyte is basically required the wide range of liquid temperature, the high electrochemical stability and the ionic conductivity at low temperature. The interface composition and structure are the key factors to exchange the charges/lithium ions, and maintain the compatibility between electrolyte and electrode. Liquid phase modification is mainly realized through the use of new lithium salts and new wide temperature co-solvents, while interface modification is mainly carried out by the addition of interface film additives and high-temperature additives.
In this paper, based on the studies of author and teammates, lots of research and exploration results on the electrolyte for wide temperature are reviewed. Novel lithium salts, co-solvents and functional additives reported in recent years are focused on their structures, properties and action mechanism. At the end, future prospect and research methods are given for lithium-ion battery electrolytes adapted wide operating temperature range.
|
|
Published: 10 April 2020
|
|
|
| Fund:This work was financially supported by the Natural Science Foundation of Anhui Province (1708085QB32), the National Natural Science Foundation of China (51576208, 11505290). |
About author:: Wenjing Pu graduated from National University of Defense Technology in December 2015, and received her Doctor’s Degree in material science and engineering. Main research direction is functional polysilane. Currently, she is a lecturer at Institute of Applied Physics, Army Academy of Artillery and Air Defense of PLA. In the research of polymer electrolytes for lithium ion battery materials, she has cooperated with Wei Lu, a lecturer at the Institutes of Physical Science and Information Technology, Anhui University. At present, four SCI papers have been published and three patents have been issued and published.
Wei Lureceived his B.E. degree in applied chemistry from National University of Defense Technology in 2008 and received his master’s and doctor’s degree in material science and engineering from National University of Defense Technology in 2010 and 2015 respectively. He is currently a lecturer at the Institutes of Physical Scie-nce and Information Technology, Anhui University. His research interests include anode and cathode materials, electrolytes and battery design and preparation. Now as the first author 10 SCI papers (including 3 in JCR1) have been published, and 4 patents have been issued and published. |
|
|
1 Chen N, Zhang H, Li L, et al. Advanced Energy Materials, 2018, 8(12), 1702675.
2 Abe Y, Kumagai S. Journal of Energy Storage, 2018, 19, 96.
3 Tsuda T, Ando N, Matsubara K, et al. Electrochimica Acta, 2018, 291, 267.
4 Chen L, Fan X, Hu E, et al. Chem, 2019,5(4),896.
5 Xu K. Chemical Review, 2014, 114(23), 11503.
6 Logan E R, Tonita E M, Gering K L, et al. Journal of the Electrochemical Society, 2018, 165(3), A705.
7 Richardson G, Foster J M, Sethurajan A K, et al. Journal of the Electrochemical Society, 2018, 165(9), H561.
8 Gowda S R, Gallagher K G, Croy J R, et al. Physical Chemistry Chemical Physics, 2014, 16, 6898.
9 Li L, Basu S, Wang Y, et al. Science, 2018, 359, 1513.
10 Lee D J, Im D, Ryu Y, et al. Journal of Power Sources, 2013, 243, 831.
11 Shimoda K, Murakami M, Takamatsu D, et al. Electrochimica Acta, 2013, 108, 343.
12 Wu B, Ren Y, Mu D, et al. International Journal of Electrochemical Scie-nce, 2013, 8, 8502.
13 Ji Y, Zhang Y, Wang C. Journal of the Electrochemical Society, 2013, 160(4), A636.
14 Nguyen C C, Lucht B L. Journal of the Electrochemical Society, 2018, 165(10), A2154.
15 Lu W, Xie K, Chen Z, et al. Journal of Power Sources, 2015, 274, 676.
16 Lu W, Xiong S, Xie K, et al. Ionics, 2016, 22(11), 2095.
17 Huang S, Cheong L, Wang D, et al. Applied Surface Science, 2018, 454, 61.
18 Lu W, Xiong S, Pu W, et al. ChemElectroChem, 2017, 4, 2012.
19 Fan L, Wei S, Li S, et al. Advanced Energy Materials, 2018, 8(11), 1702657.
20 Arturtron, Nosenko A, Park Y D, et al. Journal of Solid State Chemistry, 2018, 258, 467.
21 Liu Y, Xie K, Pan Y, et al. Ionics, 2018, 24, 723.
22 Chen S, Zheng J, Mei D, et al. Advanced Materials, 2018, 30(21), 1706102.
23 Xia L, Yu L, Hu D, et al. Acta Chimica Sinica, 2017, 75(12), 1183(in Chinese).
夏兰, 余林颇, 胡笛, 等. 化学学报, 2017, 75(12), 1183.
24 Deng B, Sun D, Wan Q, et al. Acta Chimica Sinica, 2018, 76(4), 259(in Chinese).
邓邦为, 孙大明, 万琦, 等. 化学学报, 2018, 76(4), 259.
25 Ue M. Electrolytes: Nonaqueous. Secondary Batteries-Lithium Rechar-geable Systems, Elsevier B.V. Netherlands, 2009, pp. 72.
26 Aravindan V, Gnanaraj J, Madhavi S, et al. Chemical European Journal, 2011, 17, 14326.
27 Kita F, Sakata H, Sinomoto S, et al. Journal of Power Sources, 2000, 90, 27.
28 Edmana L, Doeff M M, Ferryb A, et al. Journal of Physical Chemistry B, 2000, 104(15), 3476.
29 Xue Z, Chen C. Progress in Chemistry,2005, 17(3), 399(in Chinese).
薛照明, 陈春华. 化学进展, 2005, 17(3), 399.
30 Campion C L, Li W, Lucht B L. Journal of the Electrochemical Society, 2005, 152(12), A2327.
31 Douceya L, Revault M, Lautié A, et al. Electrochimica Acta, 1999, 44, 2371.
32 Kondo K, Sano M, Hiwara A, et al. Journal of Physical Chemistry B, 2000, 104, 5040.
33 Muhuri P K, Das B, Hazra D K. Journal of Physical Chemistry B, 1997, 101, 3329.
34 Jin Z, Xie K, Hong X. Acta Chimica Sinica,2014, 72, 11(in Chinese).
金朝庆, 谢凯, 洪晓斌. 化学学报, 2014, 72, 11.
35 Diao Y, Xie K, Hong X, et al. Acta Chimica Sinica 2013, 71, 508(in Chinese).
刁岩, 谢凯, 洪晓斌, 等. 化学学报, 2013, 71, 508.
36 Xu K. Electrolytes: Overview. Secondary batteries-lithium rechargeable systems, Elsevier B.V., Netherlands, 2009, pp. 51.
37 Salomon M. Non-Aqueous. Electrolytes, Elsevier B.V., Netherlands, 2009, pp. 160.
38 Kurzweil P, Brandt K. Overview. Secondary batteries-lithium rechargeable systems, Elsevier B.V., Netherlands, 2009, pp. 1.
39 Xu K. Chemical Review, 2004, 104, 4303.
40 Herreyre S, Huchet O, Barusseau S, et al. Journal of Power Sources, 2001, 97-98, 576.
41 Ein-Eli Y, Thomas S R, Chadha R, et al. Journal of the Electrochemical Society, 1997, 144(3), 283.
42 Logan E R, Tonita E M, Gering K L, et al. Journal of the Electrochemical Society, 2018, 165(2), A21.
43 Smart M C, Ratnakumar B V, Ryan-Mowrey V S, et al. Journal of Power Sources, 2003, 119-121, 359.
44 Yamaki J, Yamazaki I, Egashira M, et al. Journal of Power Sources, 2001, 102, 288.
45 Sato K, Zhao L, Okada S, et al. Journal of Power Sources, 2011, 196, 5617.
46 Sato K, Yamazaki I, Okada S, et al. Solid State Ionics, 2002, 148, 463.
47 Satoh T, Nambu N, Takehar M, et al. ECS Transactions, 2013, 50(48), 127.
48 Nishikawa D, Nakajima T, Ohzawa Y, et al. Journal of Power Sources, 2013, 243, 573.
49 Ihar M, Hang B T, Sato K, et al. Journal of the Electrochemical Society, 2003, 150(11), A1476.
50 Matsuda Y, Nakajima T, Ohzawa Y, et al. Journal of Fluorine Chemistry, 2011, 132(12), 1174.
51 Nakajima T, Dan K, Koh M. Journal of Fluorine Chemistry, 1998, 87, 221.
52 Smith K A, Smart M C, Prakash G K S, et al. ECS Transactions, 2008, 11(29), 91.
53 Mcmillan R, Slegr H, Shu Z X, et al. Journal of Power Sources, 1999, 81-82, 20.
54 Möller K C, Hodal T, Appel W K, et al. Journal of Power Sources, 2001, 97-98, 595.
55 Lu W, Xie K, Chen Z, et al. Journal of Fluorine Chemistry, 2014, 161, 110.
56 Lu W, Xie K, Pan Y, et al. Journal of Fluorine Chemistry, 2013, 156, 136.
57 Xu J, Yao W, Yao Y, et al. Acta Physico-Chimica Sinica, 2009, 25(2), 201(in Chinese).
许杰, 姚万浩, 姚宜稳, 等. 物理化学学报, 2009, 25(2), 201.
58 Zhang S S. Journal of Power Sources, 2006, 162, 1379.
59 Li J, Li H, Stone W, et al. Journal of the Electrochemical Society, 2018, 165(3), A626.
60 Zhang S S, Xu K, Jow T R. Journal of Power Sources, 2003, 115(1), 137.
61 Luo X. Journal of Alloys and Compounds, 2018, 730, 23.
62 Seki S, Takei K, Miyashiro H, et al. Journal of Electrochemistry Society, 2011, 158(6), A769.
63 Ryou M, Lee J, Lee D J, et al. Electrochimica Acta, 2013, 102, 97.
64 Wu B, Pei F, Yuewu, et al. Journal of Power Sources, 2013, 227, 106.
65 Zeng Z, Jiang X, Wu B, et al. Electrochimica Acta, 2014, 129, 300.
66 Liu J, Song X, Zhou L, et al. Nano Energy, 2018, 46, 404.
67 Takeuchi S, Fukutsuka T, Miyazaki K, et al. Journal of Power Source, 2013, 238, 65.
68 Markovsky B, Rodkin A, Cohen Y S, et al. Journal of Power Sources, 2003, 119-121, 504.
69 Markovsky B, Nimberger A, Talyosef Y, et al. Journal of Power Sources, 2004, 136, 296.
70 Aurbach D, Talyosef Y, Markovsky B, et al. Electrochimica Acta, 2004, 50, 247.
71 Guo A, Feng S, Mi Y, et al. Applied Mechanics and Materials, 2013, 327, 128.
72 Aurbach D, Gnanaraj J S, Geissler W, et al. Journal of Electrochemistry Society, 2004, 151(1), A23.
73 Li X, Xue Z, Zhao J, et al. Journal of Power Sources, 2013, 235, 274.
74 Zhang S S. Electrochemistry Communications, 2006, 8, 1423.
75 Zhou H, Liu F, Li J, et al. Journal of Inorganic Materials 2013, 28(5), 507(in Chinese).
周宏明, 刘芙蓉, 李荐, 等. 无机材料学报, 2013, 28(5), 507.
76 Zhou H, Fang Z, Li J. Journal of Power Sources, 2013, 230, 148.
77 Schedlbauer T, Rodehorst U C, Schreiner C, et al. Electrochimica Acta, 2013, 107, 26.
78 Li S, Zhao W, Zhao Y, et al. RSC Advance, 2013, 3(35), 14942.
79 Li B, Zhao W, Cui X, et al. Electrochimica Acta, 2014, 129, 327.
80 Smart M C, Ratnakumar B V, Whitacre J F, et al. Journal of Electrochemistry Society, 2005, 152(6), A1096.
81 Smart M C, Ratnakumar B V, Surampudi S. Journal of Electrochemistry Society, 1999, 146(2), 486.
82 Plichta E J, Behl W K. Journal of Power Sources, 2000, 88, 192.
83 Plichta E J, Hendrickson M, Thompson R, et al. Journal of Power Sources, 2001, 94, 160.
84 Smart M C, Ratnakumar B V, Whitcanack L D, et al. Journal of Power Sources, 2003, 119-121, 349.
85 Matsuoka O, Hiwara A, Omi T, et al. Journal of Power Sources, 2002, 108, 128.
86 Shu Z X, Mcmillan R S, Murray J J, et al. Journal of Electrochemistry Society, 1995, 142(9), L161.
87 Shu Z X, Mcmillan R S, Murray J J, et al. Journal of Electrochemistry Society, 1996, 143(7), 2230.
88 Nie M, Abraham D P, Chen Y, et al. Journal of Physical Chemistry C, 2013, 117, 13403.
89 Contestabile M, Morselli M, Paraventi R, et al. Journal of Power Sources, 2003, 119-121, 943.
90 Aurbach D, Gamolsky K, Markovsky, et al. Electrochimica Acta, 2002, 47, 1423.
91 Nakahara H, Yoon S, Nutt S. Journal of Power Sources, 2006, 160, 548.
92 Aurbach D. Journal of Power Sources, 2005, 146, 71.
93 Takeuchi T, Noguchi S, Morimoto H, et al. Journal of Power Sources, 2010, 195, 580.
94 Pu W, Li X, Li G, et al. Polymer Bulletin, 2015, 72(4), 779.
95 Pu W, Wang C, Hu T, et al. Acta Polymerica Sinica, 2015(7), 742(in Chinese).
浦文婧, 王春宇, 胡天娇, 等. 高分子学报, 2015(7), 742.
96 郑春满, 李山河, 芦伟, 等. 中国专利,专利ZL201410782778.2, 2017. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2020, Vol. 34 
