Waste-induced pyrolytic carbon nanotube forest as a catalytic host electrode for high-performance aluminum metal anodes

Authors
Son HaJong Chan HyunKWAK, JIN HWANLim, Hee DaeBeom Sik YounSungmin ChoHyoung-Joon JinHyung-Kyu LimSang Moon LeeYoung Soo Yun
Issue Date
2022-06
Publisher
Elsevier BV
Citation
Chemical Engineering Journal, v.437
Abstract
A multivalent aluminum metal anode (AMA) can deliver high specific/volumetric capacities of 2,980 mA h g(-1)/8,040 mA h cm(-3) in an ionic liquid-AlCl3 electrolyte system. However, the large concentration overpotential of AMA induced by its distinctive anion-mediated aluminum metal redox mechanism causes poor rate capabilities and insufficient round-trip efficiencies, limiting its application in rechargeable aluminum batteries (RABs). In this paper, we report a novel strategy of using a carbonaceous catalytic host electrode for high-performance AMA. The targeted carbon electrode should have a high active surface area, strong interaction with ionic charge carriers, well-developed electronic pathways, and macroporous internal structures to accommodate incessantly deposited metals. In this regard, a 3D-structured carbon nanotube forest (CNT-F) was fabricated from waste polyolefins by a simple pyrolysis process as an optimal candidate for the catalytic host electrode. The waste-induced pyrolytic CNT-Fs (WP-CNT-F) had large open surface areas covered with multitudinous intrinsic carbon defects, on which uniform aluminum reduction reactions occurred concurrently, leading to significantly lower concentration overpotentials. In addition, the WP-CNT-Fs exhibited high coulombic efficiencies of 99.4-99.8% over a wide range of current densities (0.5-4.0 mA cm(-2)) and great cycling stabilities over 1,000 cycles. The superior electrochemical performances of the WP-CNT-F-based AMA were demonstrated in the RAB full cells with a commercial graphite cathode, affording a high specific energy and a high power density of - 132.2 W h kg(electrode)(-1) and 10,230 W kg(electrode)(-1), respectively, along with outstanding cycling stabilities over 2,500 cycles.
Keywords
Aluminum batteries; Dual ion batteries; Aluminum metal anode; Pyrolytic carbon; Waste plastic; Multivalent ion
ISSN
1385-8947
URI
https://pubs.kist.re.kr/handle/201004/76697
DOI
10.1016/j.cej.2022.135416
Appears in Collections:
KIST Article > 2022
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