2018-Sustainable Industrial Processing Summit
SIPS2018 Volume 9. Energy Production, Secondary Battery
| Editors: | F. Kongoli, H. Dodds, M. Mauntz, T. Turna, V. Kumar, K. Aifantis |
| Publisher: | Flogen Star OUTREACH |
| Publication Year: | 2018 |
| Pages: | 170 pages |
| ISBN: | 978-1-987820-98-0 |
| ISSN: | 2291-1227 (Metals and Materials Processing in a Clean Environment Series) |
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Internal Hybrid Li-ion Battery-Capacitor Energy Storage Cells
Annadanesh Shellikeri1; Mark Andrew Hagen1; Jin Yan2; W.J. Cao2; Richard Jow3; Jeffrey A. Read3; Jim Zheng1;1FLORIDA A&M UNIVERSITY AND FLORIDA STATE UNIVERSITY, Tallahassee, United States; 2GENERAL CAPACITOR LLC, Tallahassee, United States; 3U.S. ARMY RESEARCH LABORATORY, Adelphi, United States;
Type of Paper: Keynote
Id Paper: 283
Topic: 14
Abstract:
As a new generation of supercapacitor, the Li-ion capacitor (LIC) is an advanced energy storage device which consists of an electric double-layer capacitor (EDLC) cathode and a pre-lithiated anode [1,2], between which the ions shuttle during charge and discharge processes. Because of using pre-lithiated and low surface anode materials, the LIC can be charged to a maximum voltage as high as 4.0 V, which is much higher than of EDLCs and comparable to Li-ion batteries (LIBs); therefore, it allows the LIC and LIB to be assembled in one package as a LIB/LIC hybrid energy storage cell.
We have demonstrated a new hybrid energy storage cell that combines the advantages of both the LIB and the LIC [3], thereby avoiding their inherent defects, while bridging the gap between the high energy densities offered by batteries and the high power densities seen in EDLCs. The energy density and power density of the hybrid cell can be designed to meet the requirements by a reasonable distribution of the ratio between LIB and LIC electrode materials in the internal hybrid cell. For example, we show a hybrid LIC consisting of a Li nickel cobalt manganese oxide (NMC)/activated carbon (AC) composite cathode in combination with an ultra-thin Li film (u-Li) pre-loaded hard carbon anode. Additionally, we show that by utilizing three design approaches: dry composite electrode fabrication method, cathode to anode capacity ratio design, and pre-lithiation method using u-Li, we can demonstrate an energy storage device with excellent cycle life, and that can be tailored by composite ratios within the cathode to fit different applications. Shown here is an in-depth look at various composite material ratios, pre-lithiation calculations and hybrid Li-ion battery-capacitor energy storage device creation based on targeting essential energy-power performance characteristics.
Keywords:
Anodes; Capacitors; Cathodes; Energy; Li-Ion; Lithium; SecondaryBattery;References:
[1] W.J. Cao and J.P. Zheng, "Li-ion Capacitors with Carbon Cathode and Hard Carbon/SLMP Anode Electrodes", J. Power Sources, 213, 180 (2012).[2] W.J. Cao, J. Shih, J.P. Zheng, and T. Doung, "Development and characterization of Li-ion capacitor pouch cells", J. Power Sources, 257, 388 (2014).
[3] Zheng, J.-S., Zhang, L., Shellikeri, A., Cao, W., Wu, Q., & Zheng, J. P. (2017). A hybrid electrochemical device based on a synergetic inner combination of Li ion battery and Li ion capacitor for energy storage. Scientific Reports, 7, 41910.