Preparation of Carbon Nanotubes Loaded RuO2 Nanoparticles and the Performance of Li-CO2 Battery

Abstract

Abstract: The Li-CO₂ battery captures CO₂ gas and converts it into electricity, which can not only alleviate the greenhouse effect, but also provide a higher theoretical energy density, which has attracted wide attention from researchers. However, Li-CO₂ batteries still face some thorny problems, such as high overpotential and poor cycle life. Electrocatalysts that efficiently promote the reduction of CO₂ and the decomposition of discharge products play a key role in Li-CO₂. Using hydrated ruthenium trichloride solution as the precursor, ruthenium dioxide (RuO₂) nanoparticles were uniformly loaded on the carbon nanotube (CNT) substrate by a simple hydrothermal method, and the ruthenium dioxide nanoparticles were successfully prepared with uniform dispersion and RuO₂-CNT catalytic cathode with three-dimensional porous structure. Under the dual action of the three-dimensional porous structure formed by cross-linked carbon nanotubes and the high-efficiency catalytic activity of RuO₂ nanoparticles, the discharge capacity and cycle performance of the Li-CO₂ battery are significantly improved. At a current density of 100 mA·g^-1, the first discharge specific capacity can reach 1 912 mAh·g^-1. In addition, under the conditions of a current density of 100 mA·g^-1 and a constant capacity of 500 mAh·g^-1, it can be cycled stably for 120 cycles. It provides a new idea for the design and preparation of Li-CO₂ battery catalytic cathode.

Key words: RuO₂, 3D porous channel structure, carbon nanotube, cathode catalyst, Li-CO₂ battery

CLC Number:

TQ152
TM912

GU Yang, WANG Zhen, LI Xue, XIAO Jie, ZENG Xiaoyuan. Preparation of Carbon Nanotubes Loaded RuO₂ Nanoparticles and the Performance of Li-CO₂ Battery[J]. Journal of Synthetic Crystals, 2021, 50(3): 542-547.

References

[1] ZHANG B W, JIAO Y, CHAO D L, et al.Targeted synergy between adjacent Co atoms on graphene oxide as an efficient new electrocatalyst for Li-CO₂ batteries[J]. Advanced Functional Materials, 2019, 29(49): 1904206.
[2] SONG L, WANG T, WU C, et al.A long-life Li-CO₂ battery employing a cathode catalyst of cobalt-embedded nitrogen-doped carbon nanotubes derived from a Prussian blue analogue[J]. Chemical Communications (Cambridge, England), 2019, 55(85): 12781-12784.
[3] LIU Y L, WANG R, LYU Y C, et al.Rechargeable Li/CO₂-O₂ (2:1) battery and Li/CO₂ battery[J]. Energy & Environmental Science, 2014, 7(2): 677-681.
[4] LI C, GUO Z Y, YANG B C, et al.A rechargeable Li-CO₂ battery with a gel polymer electrolyte[J]. Angewandte Chemie (International Ed in English), 2017, 56(31): 9126-9130.
[5] QIE L, LIN Y, CONNELL J W, et al.Highly rechargeable lithium-CO₂ batteries with a boron- and nitrogen-codoped holey-graphene cathode[J]. Angewandte Chemie International Edition, 2017, 56(24): 6970-6974.
[6] ZHAO Z W, HUANG J, PENG Z Q.Achilles’ heel of lithium-air batteries: lithium carbonate[J]. Angewandte Chemie International Edition, 2018, 57(15): 3874-3886.
[7] WU G, LI X, ZHANG Z, et al.Design of ultralong-life Li-CO₂ batteries with IrO₂ nanoparticles highly dispersed on nitrogen-doped carbon nanotubes[J]. Journal of Materials Chemistry A, 2020, 8(7): 3763-3770.
[8] ZHANG X, ZHANG Q, ZHANG Z, et al.Rechargeable Li-CO₂ batteries with carbon nanotubes as air cathodes[J]. Chemical Communications (Cambridge, England), 2015, 51(78): 14636-14639.
[9] LI X L, ZHOU J W, ZHANG J X, et al.Bamboo-like nitrogen-doped carbon nanotube forests as durable metal-free catalysts for self-powered flexible Li-CO₂ batteries[J]. Advanced Materials, 2019, 31(39): 1903852.
[10] ZHAO H M, LI D D, LI H D, et al.Ru nanosheet catalyst supported by three-dimensional nickel foam as a binder-free cathode for Li-CO₂ batteries[J]. Electrochimica Acta, 2019, 299: 592-599.
[11] XU S M, REN Z C, LIU X, et al.Carbonate decomposition: low-overpotential Li-CO₂ battery based on interlayer-confined monodisperse catalyst[J]. Energy Storage Materials, 2018, 15: 291-298.
[12] ZHANG Z, ZHANG Q, CHEN Y N, et al.The first introduction of graphene to rechargeable Li-CO₂ batteries[J]. Angewandte Chemie International Edition, 2015, 54(22): 6550-6553.
[13] GUO Z Y, LI J L, QI H C, et al.A highly reversible long-life Li-CO₂ battery with a RuP₂-based catalytic cathode[J]. Small, 2019, 15(29): 1803246.

[1]	TIAN Ye, YAN Zhe, LIU Jianxin, FAN Caimei. Preparation of RuO₂/BiOCl Composite Photocatalysts and Its Nitrogen Fixation Performance [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2023, 52(10): 1872-1879.
[2]	MIAO Zhongzheng. Theoretical Studies on Condition Control and Photoelectric Properties of Armchair Carbon Nanotubes Filled with TiCl₄ Molecular [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2022, 51(2): 324-332.
[3]	CHEN Longbo, WANG Yuelei, ZHONG Liangwei, GUO Jilin, ZENG Zhipeng, ZENG Xiaoshu. Purifying Carbon Nanotubes at Different Temperatures by Acheson Furnace [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2022, 51(11): 1911-1920.
[4]	GU Yang, WANG Zhen, WU Hongkun, XIAO Jie, ZENG Xiaoyuan. Research Progress of Key Materials for Lithium Carbon Dioxide Batteries [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2021, 50(6): 1170-1179.
[5]	JIANG Yan;WANG Tian-shuang;WANG Jiao;SHEN Jie;LIU Gui-li. Stress Distribution of Carbon Nanotubes Reinforced Magnesium Matrix Composites Containing Crack Defects under Tensile Loading [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2017, 46(6): 1184-1190.
[6]	MA Hua-li;HUO Hai-bo;ZENG Fan-guang;XIANG Fei;WANG Gan-ping. Effect of Micro-pyramid Array on Intense Pulsed Emission Characteristics of Carbon Nanotube Thin Films [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2016, 45(6): 1581-1584.
[7]	YUE Li-fu;SUN Xiao-gang;PANG Zhi-peng;WU Xiao-yong;NIE Yan-yan;LIU Zhen-hong. Research of Whisker-multi-walled Carbon Nanotube Conductive Solution and Transparent Conducting Thin Film [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2016, 45(2): 381-387.
[8]	DING Kai-xiang;SUN Bao-min;GUO Yong-hong;JIA Xiao-wei;WANG Yang;KANG Zhi-zhong. Effect of Catalyst Calcination Temperature and Acetylene Flame Temperature on Carbon Nanotubes Synthesized from C2H4 by Flame Method [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2016, 45(1): 41-46.
[9]	MA Tao;YANG Xue-feng;YAO Kong;LI Yun-xi;WANG Cheng-min. Friction Characteristics of Al2O3/TiC Ceramic Conical Die Composite with MWCNTs [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(9): 2583-2589.
[10]	LIU Zhen-hong;SUN Xiao-gang;WU Xiao-yong;PANG Zhi-peng;NIE Yan-yan;YUE Li-fu. Performance of Lithium Ion Batteries Using a Carbon Nanotube Conductive Paper as a Anode Current Collector [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(7): 1778-1782.
[11]	ZHOU Biao;CHENG Xi-yun;PENG Mei-hua;ZHANG Jian-feng;YAN Mao-wei. Preparation of Functionalized Magnetic Carbon Nanotubes and Research on Mechanical Properties of Construct Ordered Carbon Nanotubes Materials [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(7): 1843-1848.
[12]	DING Kai-xiang;SUN Bao-min;WANG Yang;GUO Yong-hong;KANG Zhi-zhong. Effect of Sampling Time and Carbon Source Gas Flow Rate on the Carbon Nanotubes Synthesized from C2H4 by Flame Method [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(6): 1619-1624.
[13]	WU Xiao-yong;SUN Xiao-gang;PANG Zhi-peng;FU Qi;CHENG Xiao-yuan. Preparation of Flexible Carbon Nanotubes Composite Conductive Paper and Its Application in Zinc-manganese Batteries [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(5): 1240-1246.
[14]	CHEN Ming-dong;JIE Xiao-hua;YU Huang-zhong;ZHANG Hai-yan;LI Jing-hui. Absorbing Properties of Carbon Nanotubes/Cobalt Ferrites Composite Materials and Its Optimization [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(2): 487-492.
[15]	TANG Dong-mei;FU Zhi-bing;YI Yong;WANG Chao-yang;TANG Chang-huan. Preparation and Characterization of the Centripetal Carbon Nanotube Arrays [J]. JOURNAL OF SYNTHETIC CRYSTALS, 2015, 44(2): 525-529.

Preparation of Carbon Nanotubes Loaded RuO₂ Nanoparticles and the Performance of Li-CO₂ Battery

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments