A Lithium-ion capacitor (LIC) is composed of an electrochemical capacitor-like cathode and battery-like anode which store charge based on non-faradaic and faradaic processes, respectively. As an anode material for LIC, graphite is widely used because of its physical and electrochemical advantages. In the LIC system, stable cyclability at the high rate conditions is essential for bridging the gap between lithium-ion batteries and supercapacitors. However, there have been reported that the low working potential of graphite (close to 0.05 V vs Li/Li+) causes Li plating on the graphite surface and non-unity coulombic efficiency at high current charge/discharge results in degradation of cycle performance. To overcome this issue, stacked reduced graphene oxide-tin (SrGO-Sn) composite by co-reduction of graphene oxide and Sn2+ are studied in this work. The LIC consisting of SrGO-Sn anode shows good long-term cyclability with a remarkable capacity retention of 85, 77, and 60% at 10,000, 50,000, and 100,000th cycle and coulombic efficiency of 98% after 120,000 cycles. We believe that this study presents a new approach to the design of the high-performance LIC using an alternative to conventional graphite-based anode materials.
AlCl3-graphite intercalation compounds (AlCl3-GICs) with a wide interlayer spacing benefit faster Li+ diffusion. The low molecular weight and conversion reaction of the AlCl3 pillar further enhance the specific capacity per mass.
Lithium-ion capacitors (LIC) are hybrid energy storage devices combining electric double layer capacitors (EDLC) and lithium-ion batteries (LIB). In typical LIC systems, faradaic reaction on anode restricts high power performance because of slow reaction rate than that of non-faradaic reaction on cathode. The conventional graphite anode suffers from low rate capability for LIC and shows low theoretical capacity which is not suitable for high energy density. To achieve high rate performance and high capacity, ferric chloride-graphite intercalation compounds (FeCl3-GICs) are reported as LIB anodes[1]. Intercalated FeCl3 enlarges interlayer spacing of graphite and reacts like following reaction (FeCl3+3Li++3e- ↔ Fe+3LiCl). We focused on aluminum chloride-GICs (AlCl3-GICs), lighter than FeCl3-GICs, as new anode materials for LIB and LIC. AlCl3-GICs have possibility of high rate performance and higher capacity at low potential by following reaction (AlCl3+3Li++3e-↔Al+3LiCl, Al+2.25Li++2.25e-↔Li2.25Al). In this paper, AlCl3-GICs were synthesized and evaluated their material characteristics and electrochemical properties. AlCl3-GICs was synthesized via vapor phase intercalation mehod[2]. First, graphite, AlCl3 and N-chlorosuccinimide as chlorinating agent were mixed under Ar atomosphere. Then, mixed powder was heated under vacuum at various temperatures (115, 135, 150, 200 ℃), forming AlCl3-GICs (named as 115, 135, 150, 200, respectively). Electrochemical properties were evaluated by galvanostatic charge/discharge test at various current densities with assembled Li//AlCl3-GIC cells. As experimental condition, electrolyte was 1M LiPF6 in EC/DEC (1/1 vol.), voltage range was 0.01–3.0 V and current density values were 0.1–2.0 A g-1. Fig. 1 shows XRD patterns of obtained AlCl3-GICs. Peaks derived from GICs were confirmed for all AlCl3-GICs. The different intensity ratio of pristine(002)/GIC(00x) of the AlCl3-GICs synthesized with different heating temperature indicated various intercalated structures. Fig. 2 shows rate performance of the Li//AlCl3-GIC cells. From this result, it was confirmed that AlCl3-GICs could react with Li+ and showed over 70 mAh g-1 even at high current density such as 2.0 A g-1 (over 4 C-rate). The results demonstrated high rate performance of AlCl3-GICs as anode for LIB and LIC. We have considered that the high rate capability can be due to improvement of Li+ diffusibility caused by enlarging interlayer spacings and/or increase of active surface area. Especially, 115 shows the discharge capacity of 432 mAh g-1, which is higher than theoretical capacity of graphite (372 mAh g-1) and the highest capacities among GICs at all current densities. Therefore, AlCl3-GICs have possibility as the anode for high performance LIC. In the poster, details of characteristics and application to LIC will be discussed. Acknowledgements This work is partially supported by the Advanced Low Carbon Technology Research and Development Program of the Japan Science and Technology Agency (JST-ALCA, JPMJAL1008, JPMJAL1301). Reference [1] Y. Sun et al., Energy Technol., 7, 1801091 (2019). [2] H. Shioyama, Tanso, 161, 35-37 (1993). Figure 1
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