Nitrogen-doped carbonized polyimide microsphere as a novel anode material for high performance lithium ion capacitors

• Published in: Electrochimica acta Vol. 196; pp. 603 - 610
• Main Authors: Han, Xiaoqi, Han, Pengxian, Yao, Jianhua, Zhang, Shu, Cao, Xiaoyan, Xiong, Junwei, Zhang, Junnan, Cui, Guanglei
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.04.2016
• Subjects: Anodes; Capacitors; Carbonization; Electric bridges; Energy density; Lithium; Lithium ion capacitor; Microspheres; Nitrogen atoms; Nitrogen doping; Polyimide microsphere; Polyimide resins; Pre-lithiation; Carbonization; Lithium ion capacitor; Nitrogen doping; Polyimide microsphere; Pre-lithiation
• ISSN: 0013-4686; 1873-3859
• DOI: 10.1016/j.electacta.2016.02.185

•Nitrogen-doped CPIMS was synthesized through solvothermal method followed by carbonization.•LICs were assembled using pre-lithiated CPIMS anode and AC cathode.•The LIC delivers energy density of 28.5Whkg−1 at 348Wkg−1 based on electrode materials mass.•Even at 6940Wkg−1, the energy density is still remains 13.1Whkg−1.•The capacity retention ratio is as high as 97.1% after 5000 cycles at 500 mAg−1. Lithium ion capacitors (LICs), which bridge the gap between lithium ion battery and electric double layer capacitor, have recently attracted considerable attention. Herein, we first propose the possible utilization of nitrogen-doped carbonized polyimide microsphere (CPIMS) as a novel anode material of LICs. The structures and lithium intercalation properties of CPIMS treated at different temperatures are investigated. It is demonstrated that some of nitrogen atoms are kept in the CPIMS, which is helpful for improving the electrochemical performances. The CPIMS900 (900 is the carbonization temperature) can deliver specific capacities of 328.3 and 48.2mAhg−1at 10mAg−1 and 10Ag−1, respectively. When the pre-lithiated CPIMS900 is coupled with an activated carbon cathode, an energy density of 28.5Whkg−1at 348Wkg−1 is obtained based on the weight of both electrode materials. Even at 6940Wkg−1, the energy density still remains 13.1Whkg−1. After 5000 cycles at 500mAg−1, the capacity retention ratio is as high as 97.1%. The present work offers an opportunity to utilize the CPIMS material in LIC with high energy density, high power density and promising cycle life.