Preparation of biomass-derived carbon loaded with MnO2 as lithium-ion battery anode for improving its reversible capacity and cycling performance
Received date: 31 Jul 2023
Accepted date: 19 Oct 2023
Copyright
Biomass-derived carbon materials for lithium-ion batteries emerge as one of the most promising anodes from sustainable perspective. However, improving the reversible capacity and cycling performance remains a long-standing challenge. By combining the benefits of K2CO3 activation and KMnO4 hydrothermal treatment, this work proposes a two-step activation method to load MnO2 charge transfer onto biomass-derived carbon (KAC@MnO2). Comprehensive analysis reveals that KAC@MnO2 has a micro-mesoporous coexistence structure and uniform surface distribution of MnO2, thus providing an improved electrochemical performance. Specifically, KAC@MnO2 exhibits an initial charge-discharge capacity of 847.3/1813.2 mAh·g–1 at 0.2 A·g–1, which is significantly higher than that of direct pyrolysis carbon and K2CO3 activated carbon, respectively. Furthermore, the KAC@MnO2 maintains a reversible capacity of 652.6 mAh·g–1 after 100 cycles. Even at a high current density of 1.0 A·g–1, KAC@MnO2 still exhibits excellent long-term cycling stability and maintains a stable reversible capacity of 306.7 mAh·g–1 after 500 cycles. Compared with reported biochar anode materials, the KAC@MnO2 prepared in this work shows superior reversible capacity and cycling performance. Additionally, the Li+ insertion and de-insertion mechanisms are verified by ex situ X-ray diffraction analysis during the charge-discharge process, helping us better understand the energy storage mechanism of KAC@MnO2.
Likai Zhu , Huaping Lin , Wenli Zhang , Qinhui Wang , Yefeng Zhou . Preparation of biomass-derived carbon loaded with MnO2 as lithium-ion battery anode for improving its reversible capacity and cycling performance[J]. Frontiers of Chemical Science and Engineering, 2024 , 18(1) : 10 . DOI: 10.1007/s11705-023-2376-y
| 1 |
Tarascon J M , Armand M . Issues and challenges facing rechargeable lithium batteries. Nature, 2001, 414(6861): 359–367
|
| 2 |
Wang R , Cao X , Sui S , Li B , Li Q . Study on the growth of platinum nanowires as cathode catalysts in proton exchange membrane fuel cells. Frontiers of Chemical Science and Engineering, 2022, 16(3): 364–375
|
| 3 |
Wang C , Yang C , Zheng Z . Toward practical high-energy and high-power lithium battery anodes: present and future. Advanced Science, 2022, 9(9): 2105213
|
| 4 |
Liu Y , Niu Y , Ouyang X , Guo C , Han P , Zhou R , Heydari A , Zhou Y , Ikkala O , Tigranovich G A .
|
| 5 |
Rahman M A , Wong Y C , Song G S , Wen C E . A review on porous negative electrodes for high performance lithium-ion batteries. Journal of Porous Materials, 2015, 22(5): 1313–1343
|
| 6 |
Yang X Y , Li R , Yang J X , Liu H Z , Luo T , Wang X L , Yang L . A novel route to constructing high-efficiency lithium sulfur batteries with spent graphite as the sulfur host. Carbon, 2022, 199: 215–223
|
| 7 |
Zhu L , Zhu W , Cheng X B , Huang J Q , Peng H J , Yang S H , Zhang Q . Cathode materials based on carbon nanotubes for high-energy-density lithium-sulfur batteries. Carbon, 2014, 75: 161–168
|
| 8 |
Lakshmi K P , Janas K J , Shaijumon M M . Antimony oxychloride/graphene aerogel composite as anode material for sodium and lithium ion batteries. Carbon, 2018, 131: 86–93
|
| 9 |
Zhang W , Yin J , Wang C , Zhao L , Jian W , Lu K , Lin H , Qiu X , Alshareef H N . Lignin derived porous carbons: synthesis methods and supercapacitor applications. Small Methods, 2021, 5(11): 2100896
|
| 10 |
Zhou Y F , Zhu L K , Chen S D , Fu L C , Cai L , Wang Q H , Xiong Q G , Xie F H . In-depth study of synergism between torrefaction and catalyst for balanced production of bio-oil from rice husk pyrolysis based on hydrocarbons production, energy yield and deoxygenation degree. Biomass and Bioenergy, 2022, 162: 106494
|
| 11 |
Kim K , Adams R A , Kim P J , Arora A , Martinez E , Youngblood J P , Pol V G . Li-ion storage in an amorphous, solid, spheroidal carbon anode produced by dry-autoclaving of coffee oil. Carbon, 2018, 133: 62–68
|
| 12 |
Luna-Lama F , Rodríguez-Padrón D , Puente-Santiago A R , Muñoz-Batista M J , Caballero A , Balu A M , Romero A A , Luque R . Non-porous carbonaceous materials derived from coffee waste grounds as highly sustainable anodes for lithium-ion batteries. Journal of Cleaner Production, 2019, 207: 411–417
|
| 13 |
Wang L P , Schnepp Z , Titirici M M . Rice husk-derived carbon anodes for lithium ion batteries. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2013, 1(17): 5269–5273
|
| 14 |
Xiang J Y , Lv W M , Mu C P , Zhao J , Wang B C . Activated hard carbon from orange peel for lithium/sodium ion battery anode with long cycle life. Journal of Alloys and Compounds, 2017, 701: 870–874
|
| 15 |
Jin G , Zhang J , Dang B , Wu F , Li J . Engineering zirconium-based metal-organic framework-801 films on carbon cloth as shuttle-inhibiting interlayers for lithium-sulfur batteries. Frontiers of Chemical Science and Engineering, 2022, 16(4): 511–522
|
| 16 |
Mao G Q , Yu W J , Zhou Q J , Li L J , Huang Y D , Yao Y Y , Chu D W , Tong H , Guo X Y . Improved electrochemical performance of high-nickel cathode material with electronic conductor RuO2 as the protecting layer for lithium-ion batteries. Applied Surface Science, 2020, 531: 147245
|
| 17 |
Li X , Shao C L , Wang X L , Wang J J , Liu G X , Yu W S , Dong X T , Wang J X . Preparation of Fe3O4/fesheterostructures via electrochemical deposition method and their enhanced electrochemical performance for lithium-sulfur batteries. Chemical Engineering Journal, 2022, 446: 137267
|
| 18 |
Wang X , Wang J , Yu B , Jiang W , Wei J , Chen B , Xu R , Yang L . Facile synthesis MnCo2O4.5@C nanospheres modifying PbO2 energy-saving electrode for zinc electrowinning. Journal of Hazardous Materials, 2022, 428: 128212
|
| 19 |
Ren Y Q , Xiao X C , Ni J M , Zhao H , Yang H , Chen X Y . RuO2 incorporated Co3O4 nanosheets as carbon-free integrated cathodes for lithium-oxygen battery application. Materials Letters, 2021, 304: 130634
|
| 20 |
Lee H C , Kim Y A , Lee H J , Kim B H . Improved electrochemical performance of sandwich-structured N-rich C@MnO@C electrodes. Carbon, 2023, 207: 154–161
|
| 21 |
Zhang J , Tahmasebi A , Omoriyekomwan J E , Yu J . Microwave-assisted synthesis of biochar-carbon-nanotube-nio composite as high-performance anode materials for lithium-ion batteries. Fuel Processing Technology, 2021, 213: 106714
|
| 22 |
Luna-Lama F , Hernández-Rentero C , Caballero A , Morales J . Biomass-derived carbon/γ-MnO2 nanorods/s composites prepared by facile procedures with improved performance for Li/S batteries. Electrochimica Acta, 2018, 292: 522–531
|
| 23 |
Li T , Bai X , Qi Y X , Lun N , Bai Y J . Fe3O4 nanoparticles decorated on the biochar derived from pomelo pericarp as excellent anode materials for Li-ion batteries. Electrochimica Acta, 2016, 222: 1562–1568
|
| 24 |
Gueon D , Moon J H . Mnonanoflake-shelled carbon nanotube particles for high-performance supercapacitors. ACS Sustainable Chemistry & Engineering, 2017, 5(3): 2445–2453
|
| 25 |
You Y , Zhang X , Li P , Lei F , Jiang J . Co-production of xylooligosaccharides and activated carbons from Camellia oleifera shell treated by the catalysis and activation of zinc chloride. Bioresource Technology, 2020, 306: 123131
|
| 26 |
Guo X , Yang S , Wang D H , Chen A , Wang Y B , Li P , Liang G J , Zhi C Y . The energy storage mechanisms of MnO2 in batteries. Current Opinion in Electrochemistry, 2021, 30: 100769
|
| 27 |
Ji K M , Liang G H , Shen Y H , Dai H X , Han J H , Ito Y , Fujita T , Fujita J , Wang C Y , Chen M M . Ordered macroporous graphenic carbon-based framework materials and their low-temperature co-sacrificial template synthesis mechanism. Cell Reports. Physical Science, 2023, 4(2): 101283
|
| 28 |
Aghamohammadi H , Hassanzadeh N , Eslami-Farsani R . A review study on the recent advances in developing the heteroatom-doped graphene and porous graphene as superior anode materials for Li-ion batteries. Ceramics International, 2021, 47(16): 22269–22301
|
| 29 |
Yu N , Yin H , Zhang W , Liu Y , Tang Z , Zhu M Q . High-performance fiber-shaped all-solid-state asymmetric supercapacitors based on ultrathin MnO2 nanosheet/carbon fiber cathodes for wearable electronics. Advanced Energy Materials, 2016, 6(2): 1501458
|
| 30 |
Zhao N , Deng L B , Luo D W , Zhang P X . One-step fabrication of biomass-derived hierarchically porous carbon/MnO nanosheets composites for symmetric hybrid supercapacitor. Applied Surface Science, 2020, 526: 146696
|
| 31 |
Xie Y , Yang C , Chen P , Yuan D W , Guo K K . MnO2-decorated hierarchical porous carbon composites for high-performance asymmetric supercapacitors. Journal of Power Sources, 2019, 425: 1–9
|
| 32 |
Zhang L , Wang W , Lu S , Xiang Y . Carbon anode materials: a detailed comparison between Na-ion and K-ion batteries. Advanced Energy Materials, 2021, 11(11): 2003640
|
| 33 |
Nie Z , Huang Y , Ma B , Qiu X , Zhang N , Xie X , Wu Z . Nitrogen-doped carbon with modulated surface chemistry and porous structure by a stepwise biomass activation process towards enhanced electrochemical lithium-ion storage. Scientific Reports, 2019, 9(1): 15032
|
| 34 |
Yu K F , Zhang Z F , Liang J C , Liang C . Natural biomass-derived porous carbons from buckwheat hulls used as anode for lithium-ion batteries. Diamond and Related Materials, 2021, 119: 108553
|
| 35 |
Xia C L , Kang C W , Patel M D , Cai L P , Gwalani B , Banerjee R , Shi S Q , Choi W . Pine wood extracted activated carbon through self-activation process for high-performance lithium-ion battery. ChemistrySelect, 2016, 1(13): 4000–4007
|
| 36 |
Muruganantham R , Wang F M , Yuwono R A , Sabugaa M , Liu W R . Biomass feedstock of waste mango-peel-derived porous hard carbon for sustainable high-performance lithium-ion energy storage devices. Energy & Fuels, 2021, 35(13): 10878–10889
|
| 37 |
Qin Y , Tang H , Chang K , Li B , Li Y , Hou Y , Chang Z . In situ synthesis of open hollow tubular MnO/C with high performance anode materials for lithium ion batteries using kapok fiber as carbon matrix. Nanotechnology, 2019, 30(1): 015403
|
| 38 |
Zhang W , Li J , Zhang J , Sheng J , He T , Tian M , Zhao Y , Xie C , Mai L , Mu S . Top-down strategy to synthesize mesoporous dual carbon armored mno nanoparticles for lithium-ion battery anodes. ACS Applied Materials & Interfaces, 2017, 9(14): 12680–12686
|
| 39 |
Qiu H L , Yue H J , Zhang T , Li T T , Wang C Z , Chen G , Wei Y J , Zhang D . Enhanced electrochemical performance of Li2FeSiO4/C cathode materials by surface modification with AlPO4 nanosheets. Electrochimica Acta, 2016, 222: 1870–1877
|
| 40 |
Gao Y , Sun R X , Li A M , Ji G Z . Self-activation strategy toward highly porous biochar for supercapacitors: direct carbonization of marine algae. Journal of Electroanalytical Chemistry, 2021, 882: 114986
|
| 41 |
Liu D , Choi W M . Hierarchical hollow urchin-like structured MnO2 microsphere/carbon nanofiber composites as anode materials for Li-ion batteries. Current Applied Physics, 2019, 19(6): 768–774
|
| 42 |
Han Q G , Zhang W Q , Han Z W , Wang F X , Geng D , Li X , Li Y , Zhang X . Preparation of PAN-based carbon fiber@MnO2 composite as an anode material for structural lithium-ion batteries. Journal of Materials Science, 2019, 54(18): 11972–11982
|
| 43 |
Wang X , Yin M , Xue H , Su Y , Tian S . Simple microwave synthesis and improved electrochemical performance of Nb-doped MnO2/reduced graphene oxide composite as anode material for lithium-ion batteries. Ionics, 2018, 24(9): 2583–2590
|
| 44 |
Abdollahi A , Abnavi A , Ghasemi F , Ghasemi S , Sanaee Z , Mohajerzadeh S . Facile synthesis and simulation of MnO2 nanoflakes on vertically aligned carbon nanotubes, as a high-performance electrode for Li-ion battery and supercapacitor. Electrochimica Acta, 2021, 390: 138826
|
| 45 |
Luo C A , Chen Y J , Tian Q H , Zhang W , Sui Z Y . Ultrathin porous MnO2@C nanosheets for high-performance lithium-ion battery anodes. Journal of Electroanalytical Chemistry, 2023, 930: 117173
|
| 46 |
Fu L C , Xiong Q A , Wang Q H , Cai L , Chen Z H , Zhou Y F . Catalytic pyrolysis of waste polyethylene using combined CaO and Ga/ZSM-5 catalysts for high value-added aromatics production. ACS Sustainable Chemistry & Engineering, 2022, 10(29): 9612–9623
|
| 47 |
Zhan D , Wen T , Li Y Q , Zhu Y Q , Liu K , Cui P , Jia Z Y , Liu H J , Lei K L , Xiao Z A . Using peanut shells to construct a porous MnO/C composite material with highly improved lithium storage performance. ChemElectroChem, 2020, 7(1): 347–354
|
| 48 |
Fang X P , Lu X , Guo X W , Mao Y , Hu Y S , Wang J Z , Wang Z X , Wu F , Liu H K , Chen L Q . Electrode reactions of manganese oxides for secondary lithium batteries. Electrochemistry Communications, 2010, 12(11): 1520–1523
|
| 49 |
Zhang W , Zhang B , Jin H , Li P , Zhang Y , Ma S , Zhang J . Waste eggshell as bio-template to synthesize high capacity δ-MnO2 nanoplatelets anode for lithium ion battery. Ceramics International, 2018, 44(16): 20441–20448
|
| 50 |
Chen H P , Tang Z Y , Liu B , Chen W , Hu J H , Chen Y Q , Yang H P . The new insight about mechanism of the influence of K2CO3 on cellulose pyrolysis. Fuel, 2021, 295: 120617
|
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