Si具有高的储锂容量,但是其循环性能很差。采用机械合金化方法,对纯Si进行处理。同时以石墨、炭黑对纯Si进行掺杂以改善Si的循环特性。对于纯Si,随着球磨时间的延长,材料的非晶化程度增加;经过球磨后材料的平均粒径由原来的29μm变成0.2μm;由大的块状变为小的圆形颗粒。充放电结果表明未经球磨处理的纯Si的首次放电比容量较高,但放电比容量损失较大,循环性能差,而经过球磨的纯Si能增加首次放电比容量,循环性能变化不大;对纯Si采用石墨、炭黑掺杂后材料的首次放电比容量下降,循环性能有所提高;球磨和掺杂没有改变Si储锂的电位。经过阻抗分析发现,球磨后纯Si材料中Li的扩散系数增大。
In this paper, pure Si was as the main study object,mechanical alloying method for the preparation of materials, and in the latter part of the process of materials preparation graphite added and SP doped. For pure Si materials,with increasing of MA time, the degree of amorphous increased; after MA, size of materials particle changed from 29 to 0.2μm; and the shape of the particles changd from large block to small round. In the re- search the charge and discharge results of different MA time materials were discussed. The results showed that Si had a high capacity in first discharge,but had large capacity loss in later cycle and poor cycling performance, after MA, the first discharge capacity of Si had increased. For doped materials, first discharge capacity decreased but cycling performance increased. In dynamic analysis, we found that MA Si had loose structure, which lead to its diffusion coefficient increased.
参考文献
[1] | M. Armand;J.-M. Tarascon .Building better batteries[J].Nature,2008(7179):652-657. |
[2] | Tarascon J M;Armand M .Issues and challenges facing rechargeable lithium batterie[J].Nature,2001,414(15):359-367. |
[3] | PATRICE SIMON;YURY GOGOTSI .Materials for electrochemical capacitors[J].Nature materials,2008(11):845-854. |
[4] | Miller J R;Simon P .Materials science electrochemical ca pacitors for energy management[J].Science,2008,321:651-652. |
[5] | Kazuyuki Adachi;Hidehiko Tajima;Tsutomu Hashimoto;Katsuaki Kobayashi .Development of 16 kWh power storage system applying Li-ion batteries[J].Journal of Power Sources,2003(119/121):897-901. |
[6] | Wu Wen;Wang Xianyou;Wang Xin et al.Studies on preparation and electrochemical performances of FeF3(H2 0)o.33 cathode material for the application of lithium.rechargeable battery[J].Journal of Functional Materials,2008,39(02):250-253. |
[7] | Hao Sun;Xiangming He;Jianguo Ren;Jianjun Li;Changyin Jiang;Chunrong Wan .Hard carbon/lithium composite anode materials for Li-ion batteries[J].Electrochimica Acta,2007(13):4312-4316. |
[8] | L.J. Fu;K. Endo;K. Sekine .Studies on capacity fading mechanism of graphite anode for Li-ion battery[J].Journal of Power Sources,2006(1):663-666. |
[9] | Chang K B;Jai P .Consideration of carbon structure effect on thermal stability of carbon anode for Li-ion re- chargeable batteries[J].Thermochimica Acta,2011,520(1-2):92-98. |
[10] | Zaghib K;Striebel K .LiFePO4/polymer/natural graph- ite:low cost Li-ion batterie[J].Electrochimica Acta,2004,50(2-3):263-270. |
[11] | S. Bourderau;T. Brousse;D.M. Schleich .Amorphous silicon as a possible anode material for Li-ion batteries[J].Journal of Power Sources,1999(0):233-236. |
[12] | Ulldemolins M;Le Cras F .Investigation on the part played by the solid electrolyte interphase on the electro- chemical performance of silicon electrode for lithium-ion batteries[J].Journal of Power Sources,2012,206(15):245-252. |
[13] | P. Birke;W.F. Chu W. Weppner .Materials for lithium thin-film batteries for application in silicon technology[J].Solid state ionics,1996(1/2):1-15. |
[14] | Koch C C;Whittenberger J D .Mechanical milling/allo- ying of intermetallics[J].Intermetallics,1996,4(05):339-355. |
[15] | Rao Huangyun;Lin Fan;Jiang Dongmei .Moessbauer spectrum study on Fe0.85 Cr0.3s--x Vx alloys prepared by arc-melting and mechanical alloying[J].Journal of Functional Materials,2008,39(08):1380-1382. |
[16] | D. Aurbach;B. Markovsky;I. Weissman;E. Levi;Y. Ein-Eli .On the correlation between surface chemistry and performance of graphite negative electrodes for Li ion batteries[J].Electrochimica Acta,1999(1/2):67-86. |
[17] | Q. Si .A high performance silicon/carbon composite anode with carbon nanofiber for lithium-ion batteries[J].Journal of Power Sources,2010(6):1720. |
[18] | Kim BC;Uono H;Sato T;Fuse T;Ishihara T;Senna M .Li-ion battery anode properties of Si-carbon nanocomposites fabricated by high energy multiring-type mill[J].Solid state ionics,2004(1/4):33-37. |
[19] | Juchen Guo;Ann Sun;Xilin Chen;Chunsheng Wang;Ayyakkannu Manivannan .Cyclability study of silicon-carbon composite anodes for lithium-ion batteries using electrochemical impedance spectroscopy[J].Electrochimica Acta,2011(11):3981-3987. |
[20] | Yoon Seok Jung;Kyu T. Lee;Seung M. Oh .Si-carbon core-shell composite anode in lithium secondary batteries[J].Electrochimica Acta,2007(24):7061-7067. |
[21] | 刘鸿鹏,乔文明,詹亮,凌立成.原位生长纳米炭纤维/硅复合材料及其储锂性能[J].新型炭材料,2009(02):124-130. |
[22] | Levi M D;Aurbach D .The application of electroanalyti- cal methods to analysis of phase transitions during inter- calation of ions[J].Solid State Electrochemistry,2007,11(1-2):1031-1042. |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%