工程科学学报
工程科學學報
공정과학학보
Journal of University of Science and Technology Beijing
2015年
8期
1044-1048
,共5页
王建平%田文怀%杨道均%吴宁宁
王建平%田文懷%楊道均%吳寧寧
왕건평%전문부%양도균%오저저
锂离子电池%复合材料%负极材料%热解%电化学性能
鋰離子電池%複閤材料%負極材料%熱解%電化學性能
리리자전지%복합재료%부겁재료%열해%전화학성능
lithium-ion batteries%composite materials%anode materials%pyrolysis%electrochemical properties
采用高温热解方法成功地合成了高容量硅/碳复合负极材料.通过X射线衍射分析、热重分析、扫描电子显微镜观察、透射电子显微镜观察、恒电流充放电测试、循环伏安法等手段研究了复合材料的性能.结果表明:硅/碳复合材料由Si、C以及少量SiO2组成;硅/碳复合材料中碳的质量分数约在39%左右;经电化学性能测试,在电流0.2 mA下,该硅/碳复合材料首次充电容量768 mAh·g-1,首次库仑效率75.6%,70次循环后可逆比容量仍为529 mAh·g-1,平均容量衰减率为0.44%.这些性能改善归因于硅/碳复合材料中碳的引进,硅表面存在的碳涂层提供了一个快速锂运输通道,降低了电池的阻抗并且充放电过程中稳定了电极的组成.
採用高溫熱解方法成功地閤成瞭高容量硅/碳複閤負極材料.通過X射線衍射分析、熱重分析、掃描電子顯微鏡觀察、透射電子顯微鏡觀察、恆電流充放電測試、循環伏安法等手段研究瞭複閤材料的性能.結果錶明:硅/碳複閤材料由Si、C以及少量SiO2組成;硅/碳複閤材料中碳的質量分數約在39%左右;經電化學性能測試,在電流0.2 mA下,該硅/碳複閤材料首次充電容量768 mAh·g-1,首次庫崙效率75.6%,70次循環後可逆比容量仍為529 mAh·g-1,平均容量衰減率為0.44%.這些性能改善歸因于硅/碳複閤材料中碳的引進,硅錶麵存在的碳塗層提供瞭一箇快速鋰運輸通道,降低瞭電池的阻抗併且充放電過程中穩定瞭電極的組成.
채용고온열해방법성공지합성료고용량규/탄복합부겁재료.통과X사선연사분석、열중분석、소묘전자현미경관찰、투사전자현미경관찰、항전류충방전측시、순배복안법등수단연구료복합재료적성능.결과표명:규/탄복합재료유Si、C이급소량SiO2조성;규/탄복합재료중탄적질량분수약재39%좌우;경전화학성능측시,재전류0.2 mA하,해규/탄복합재료수차충전용량768 mAh·g-1,수차고륜효솔75.6%,70차순배후가역비용량잉위529 mAh·g-1,평균용량쇠감솔위0.44%.저사성능개선귀인우규/탄복합재료중탄적인진,규표면존재적탄도층제공료일개쾌속리운수통도,강저료전지적조항병차충방전과정중은정료전겁적조성.
Silicon/carbon composites as anode materials for lithium batteries with high power capacity were synthesized by a high temperature pyrolysis method. The performances of the silicon/carbon composites were investigated by X-ray diffraction, thermogravi-metric analysis, scanning electron microscopy, transmission electron microscopy, galvanostatic cell cycling, and cyclic voltammetry. It is found that the silicon/carbon composites consist of silicon, carbon and few silicon dioxide phases, and the carbon content is about 39%. Electrochemical cycling tests of button cells show that the specific capacity is far more than that of carbon materials. The initial charge capacity of the silicon/carbon composites is 768 mAh·g-1 at a current of 0. 2 mA and the initial coulombic efficiency is 75. 6%. After 70 cycles the reversible specific capacity is 529. 0 mAh·g-1 and the average capacity deterioration rate of each cycle is 0. 44%. These improvements can be attributed to the introduction of carbon in the Si/C composites and carbon coatings on the Si surface, which provide a rapid lithium transport pathway, reduce the cell impedance and stabilize the electrode structure during charge/discharge cycles.