Three-dimensional interconnected graphene network-based high-performance air electrode for rechargeable zinc-air batteries

Jia-Xing An; Yu Meng; Hong-Bo Zhang; Yuanzhi Zhu; Xiaohua Yu; Ju Rong; Peng-Xiang Hou; Chang Liu; Hui-Ming Cheng; Jin-Cheng Li

doi:10.1002/sus2.201

SusMat ›› 2024, Vol. 4 ›› Issue (3) : e201 DOI: 10.1002/sus2.201

RESEARCH ARTICLE

Three-dimensional interconnected graphene network-based high-performance air electrode for rechargeable zinc-air batteries

Author information +

History +

PDF

Abstract

Although zinc-air batteries (ZABs) are regarded as one of the most prospective energy storage devices, their practical application has been restricted by poor air electrode performance. Herein, we developed a free-standing air electrode that is fabricated on the basis of a multifunctional three-dimensional interconnected graphene network. Specifically, a three-dimensional interconnected graphene network with fast mass and electron transport ability, prepared by catalyzing growth of graphene foam on nickel foam and then filling reduced graphene oxide into the pores of graphene foam, is used to anchor iron phthalocyanine molecules with atomic Fe-N₄ sites for boosting the oxygen reduction during discharging and nanosized FeNi hydroxides for accelerating the oxygen evolution during charging. As a result, the obtained air electrode exhibited an ultra-small electrocatalytic overpotential of 0.603 V for oxygen reactions, a high peak power density of 220.2 mW cm^-2, and a small and stable charge-discharge voltage gap of 0.70 V at 10 mA cm^-2 after 1136 cycles. Furthermore, in situ Raman spectroscopy together with theoretical calculations confirmed that phase transformation of FeNi hydroxides takes place from α-Ni(OH)_x to β-Ni(OH)_x to γ-Ni^(3+δ)+OOH for the oxygen evolution reaction and Ni is the active center while Fe enhances the activity of Ni active sites.

Keywords

in situ Raman / interconnected graphene network / iron phthalocyanine / NiFe hydroxide / zinc-air battery

Cite this article

Download citation ▾

Jia-Xing An, Yu Meng, Hong-Bo Zhang, Yuanzhi Zhu, Xiaohua Yu, Ju Rong, Peng-Xiang Hou, Chang Liu, Hui-Ming Cheng, Jin-Cheng Li. Three-dimensional interconnected graphene network-based high-performance air electrode for rechargeable zinc-air batteries. SusMat, 2024, 4(3): e201 DOI:10.1002/sus2.201

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Zhong X, Zheng Z, Xu J, et al. Flexible zinc-air batteries with ampere-hour capacities and wide-temperature adaptabilities. Adv Mater. 2023;35(13):2209980.

[2]	Zhao C-X, Liu J-N, Wang J, Ren D, Li B-Q, Zhang Q. Recent advances of noble-metal-free bifunctional oxygen reduction and evolution electrocatalysts. Chem Soc Rev. 2021;50(13):7745-7778.

[3]	Jiao M, Dai L, Ren H-R, et al. A polarized gel electrolyte for wide-temperature flexible zinc-air batteries. Angew Chem Int Ed. 2023;62(20):e202301114.

[4]	Yang H, Gao S, Rao D, Yan X. Designing superior bifunctional electrocatalyst with high-purity pyrrole-type CoN₄ and adjacent metallic cobalt sites for rechargeable Zn-air batteries. Energy Storage Mater. 2022;46:553-562.

[5]	Meng Y, Li J-C, Zhao S-Y, et al. Fluorination-assisted preparation of self-supporting single-atom Fe-N-doped single-wall carbon nanotube film as bifunctional oxygen electrode for rechargeable Zn-air batteries. Appl Catal B. 2021;294:120239.

[6]	Xiao X, Zheng Z, Zhong X, et al. Rational design of flexible Zn-based batteries for wearable electronic devices. ACS Nano. 2023;17(3):1764-1802.

[7]	Wang Z, Jin X, Xu R, et al. Cooperation between dual metal atoms and nanoclusters enhances activity and stability for oxygen reduction and evolution. ACS Nano. 2023;17(9):8622-8633.

[8]	Zhang X-Q, Lyu Z, Ding S, et al. Two-dimensional atomically dispersed Co-N/C oxygen reaction electrocatalysts via molten-salt-assisted pyrolysis of metal-organic frameworks. J Phys Chem. 2023;127(25):11883-11890.

[9]	He L, Hu H, Zhang H-B, Mei Y, Li J-C. Bifunctional oxygen electrocatalysts derived from metal-organic framework-hydrolyzed nanosheets for rechargeable Zn-air batteries. ACS Appl Energy Mater. 2022;5(12):14799-14806.

[10]	Li J-C, Qin X, Xiao F, et al. Highly dispersive cerium atoms on carbon nanowires as oxygen reduction reaction electrocatalysts for Zn-air batteries. Nano Lett. 2021;21(10):4508-4515.

[11]	Jiao M, Zhang Q, Ye C, et al. Recycling spent LiNi₁-x-yMnxCoyO₂ cathodes to bifunctional NiMnCo catalysts for zinc-air batteries. Proc Natl Acad Sci U S A. 2022;119(20):e2202202119.

[12]	Wang Y, Cao Q, Guan C, Cheng C. Recent advances on self-supported arrayed bifunctional oxygen electrocatalysts for flexible solid-state Zn-air batteries. Small. 2020;16(33):2002902.

[13]	Zhang H, Zhao M, Liu H, et al. Ultrastable FeCo bifunctional electrocatalyst on Se-doped CNTs for liquid and flexible all-solid-state rechargeable Zn-air batteries. Nano Lett. 2021;21(5):2255-2264.

[14]	Li J-C, Xiao F, Zhong H, et al. Secondary-atom-assisted synthesis of single iron atoms anchored on N-doped carbon nanowires for oxygen reduction reaction. ACS Catal. 2019;9(7):5929-5934.

[15]	Wang XX, Yang X, Liu H, et al. Air electrodes for flexible and rechargeable Zn−air batteries. Small Struct. 2022;3(1):2100103.

[16]	Li J-C, Hou P-X, Zhao S-Y, et al. A 3D bi-functional porous N-doped carbon microtube sponge electrocatalyst for oxygen reduction and oxygen evolution reactions. Energy Environ Sci. 2016;9(10):3079-3084.

[17]	Xia BY, Yan Y, Li N, Wu HB, Lou XW, Wang X. A metal-organic framework-derived bifunctional oxygen electrocatalyst. Nat Energy. 2016;1(1):15006.

[18]	Lei Z, Tan Y, Zhang Z, et al. Defects enriched hollow porous Co-N-doped carbons embedded with ultrafine CoFe/Co nanoparticles as bifunctional oxygen electrocatalyst for rechargeable flexible solid zinc-air batteries. Nano Res. 2021;14(3):868-878.

[19]	Ding S, Barr JA, Shi Q, et al. Engineering atomic single metal-FeN₄Cl sites with enhanced oxygen-reduction activity for high-performance proton exchange membrane fuel cells. ACS Nano. 2022;16(9):15165-15174.

[20]	Li J-C, Maurya S, Kim YS, et al. Stabilizing single-atom iron electrocatalysts for oxygen reduction via ceria confining and trapping. ACS Catal. 2020;10(4):2452-2458.

[21]	Lei H, Ma L, Wan Q, et al. Promoting surface reconstruction of NiFe layered double hydroxide for enhanced oxygen evolution. Adv Energy Mater. 2022;12(48):2202522.

[22]	Huang B, Li L, Tang X, et al. Pyrolysis-free polymer-based oxygen electrocatalysts. Energy Environ Sci. 2021;14(5):2789-2808.

[23]	Zhou T, Zhang N, Wu C, Xie Y. Surface/interface nanoengineering for rechargeable Zn-air batteries. Energy Environ Sci. 2020;13(4):1132-1153.

[24]	Liu J-N, Zhao C-X, Wang J, Ren D, Li B-Q, Zhang Q. A brief history of zinc-air batteries: 140 years of epic adventures. Energy Environ Sci. 2022;15(11):4542-4553.

[25]	Liu Z-Q, Liang X, Ma F-X, et al. Decoration of NiFe-LDH nanodots endows lower Fe-d band center of Fe1-N-C hollow nanorods as bifunctional oxygen electrocatalysts with small overpotential gap. Adv Energy Mater. 2023;13(13):2203609.

[26]	Zhang M, Li H, Chen J, et al. High-loading Co single atoms and clusters active sites toward enhanced electrocatalysis of oxygen reduction reaction for high-performance Zn-air battery. Adv Funct Mater. 2023;33(4):2209726.

[27]	Liu Y, Chen Z, Li Z, et al. CoNi nanoalloy-Co-N₄ composite active sites embedded in hierarchical porous carbon as bi-functional catalysts for flexible Zn-air battery. Nano Energy. 2022;99:107325.

[28]	Mirshokraee SA, Muhyuddin M, Lorenzi R, et al. Litchi-derived platinum group metal-free electrocatalysts for oxygen reduction reaction and hydrogen evolution reaction in alkaline media. SusMat. 2023;3(2):248-262.

[29]	Zhao C-X, Liu J-N, Li B-Q, et al. Multiscale construction of bifunctional electrocatalysts for long-lifespan rechargeable zinc-air batteries. Adv Funct Mater. 2020;30(36):2003619.

[30]	Ding S, He L, Fang L, et al. Carbon-nanotube-bridging strategy for integrating single Fe atoms and NiCo nanoparticles in a bifunctional oxygen electrocatalyst toward high-efficiency and long-life rechargeable zinc-air batteries. Adv Energy Mater. 2022;12(18):2202984.

[31]	Li J-C, Meng Y, Zhang L, et al. Dual-phasic carbon with Co single atoms and nanoparticles as a bifunctional oxygen electrocatalyst for rechargeable Zn-air batteries. Adv Funct Mater. 2021;31(42):2103360.

[32]	Zhang Y, Deng Y-P, Wang J, et al. Recent progress on flexible Zn-air batteries. Energy Storage Mater. 2021;35:538-549.

[33]	Yan X, Ha Y, Wu R. Binder-free air electrodes for rechargeable zinc-air batteries: recent progress and future perspectives. Small Methods. 2021;5(4):2000827.

[34]	Zeng K, Zheng X, Li C, et al. Recent advances in non-noble bifunctional oxygen electrocatalysts toward large-scale production. Adv Funct Mater. 2020;30(27):2000503.

[35]	Hu G, Xu C, Sun Z, et al. 3D graphene-foam-reduced-graphene-oxide hybrid nested hierarchical networks for high-performance Li-S batteries. Adv Mater. 2016;28(8):1603-1609.

[36]	Zhang H, Hwang S, Wang M, et al. Single atomic Iron catalysts for oxygen reduction in acidic media: particle size control and thermal activation. J Am Chem Soc. 2017;139(40):14143-14149.

[37]	Zhang J-Z, Zhang Z, Zhang H-B, et al. Prussian-blue-analogue-derived ultrathin Co₂P-Fe₂P nanosheets for universal-pH overall water splitting. Nano Lett. 2023;23(17):8331-8338.

[38]	Li Z, Wu X, Jiang X, et al. Surface carbon layer controllable Ni₃Fe particles confined in hierarchical N-doped carbon framework boosting oxygen evolution reaction. Adv Powder Mater. 2022;1(2):100020.

[39]	Su J, Musgrave CB, Song Y, et al. Strain enhances the activity of molecular electrocatalysts via carbon nanotube supports. Nat Catal. 2023;6(9):818-828.

[40]	Qian H, Yu G, Hou Q, et al. Ingenious control of adsorbed oxygen species to construct dual reaction centers ZnO@FePc photo-Fenton catalyst with high-speed electron transmission channel for PPCPs degradation. Appl Catal B. 2021;291:120064.

[41]	Ren L, Wen X, Du D, et al. Engineering high-spin state cobalt cations in spinel ZnCo₂O₄ for spin channel propagation and electrocatalytic activity enhancement in Li-O₂ battery. Chem Eng J. 2023;462:142288.

[42]	Tian G, Xu H, Wang X, et al. Optimizing d-orbital occupation on interfacial transition metal sites via heterogeneous interface engineering to accelerate oxygen electrode reaction kinetics in lithium-oxygen batteries. Nano Energy. 2023;117:108863.

[43]	Yan Z, Sun H, Chen X, et al. Anion insertion enhanced electrodeposition of robust metal hydroxide/oxide electrodes for oxygen evolution. Nat Commun. 2018;9(1):2373.

[44]	Hu H, Meng Y, Mei Y, et al. Bifunctional oxygen electrocatalysts enriched with single Fe atoms and NiFe₂O₄ nanoparticles for rechargeable zinc-air batteries. Energy Storage Mater. 2023;54:517-523.

[45]	Xu Z, Zhu J, Shao J, et al. Atomically dispersed cobalt in core-shell carbon nanofiber membranes as super-flexible freestanding air-electrodes for wearable Zn-air batteries. Energy Storage Mater. 2022;47:365-375.

[46]	Sun J, Guo N, Song T, et al. Revealing the interfacial electron modulation effect of CoFe alloys with CoCX encapsulated in N-doped CNTs for superior oxygen reduction. Adv Powder Mater. 2022;1(3):100023.

[47]	Liu S, Wan R, Lin Z, et al. Probing the Co role in promoting the OER and Zn-air battery performance of NiFe-LDH: a combined experimental and theoretical study. J Mater Chem. 2022;10(10):5244-5254.

[48]	Zhang Y-L, Dai Y-K, Liu B, et al. Vacuum vapor migration strategy for atom-nanoparticle composite catalysts boosting bifunctional oxygen catalysis and rechargeable Zn-air batteries. J Mater Chem. 2022;10(6):3112-3121.

[49]	Yasin G, Ali S, Ibraheem S, et al. Simultaneously engineering the synergistic-effects and coordination-environment of dual-single-atomic iron/cobalt-sites as a bifunctional oxygen electrocatalyst for rechargeable zinc-air batteries. ACS Catal. 2023;13(4):2313-2325.

[50]	Han X, Zhang W, Ma X, et al. Identifying the activation of bimetallic sites in NiCo₂S₄@g-C₃N₄-CNT hybrid electrocatalysts for synergistic oxygen reduction and evolution. Adv Mater. 2019;31(18):1808281.

[51]	Tian Y, Wu Z, Li M, et al. Atomic modulation and structure design of Fe−N₄ modified hollow carbon fibers with encapsulated Ni nanoparticles for rechargeable Zn-air batteries. Adv Funct Mater. 2022;32(52):2209273.

[52]	Zheng X, Cao X, Zeng K, et al. A self-jet vapor-phase growth of 3D FeNi@NCNT clusters as efficient oxygen electrocatalysts for zinc-air batteries. Small. 2021;17(4):2006183.