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Journal of Materials Science: Materials in Electronics
Published in: Journal of Materials Science: Materials in Electronics 6/2024

01-02-2024

Chinese baijiu spent grains-based high-performance porous hard carbon for sodium-ion battery anodes

Authors: Longhan Xu, Xiaolei Li, Qiang Zhou, Xuguang An, Jing Zhang, Weitang Yao, Xiaonan Liu, Qingquan Kong

Published in: Journal of Materials Science: Materials in Electronics | Issue 6/2024

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Abstract

Hard carbon is considered to be a viable choice for anode materials in sodium-ion batteries due to its low cost and high specific capacity for sodium storage. The wasted grains derived from Chinese baijiu possess significant potential as biomass-based precursors for the production of hard carbon compounds. However, their use as biomass material has been mostly ignored. Therefore, this research focuses on the use of discarded grains from baijiu as a raw material for the production of porous hard carbon materials, specifically for the anode of sodium-ion batteries. The proposed synthesis procedure involves the use of a ZnCl2 chemical treatment to generate hard carbon materials that possess a porous structure and exhibit graphitic features. In comparison to the direct carbonization synthesis process, the use of ZnCl2 treatment on porous hard carbon results in notable enhancements in electrochemical performance, including specific capacity and rate capability, while simultaneously preserving exceptional long-term cycle stability. Especially, the enhanced capacity mostly manifests in the low-voltage plateau region, and the high plateau capacity can maintained even at higher specific currents, which is suitable for high-rate application, exceeding the typical commercial hard carbon materials used in sodium-ion batteries.
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Appendix
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Literature
1.
W. Nitta Naoki, L.J. Feixiang, Tae, Li-ion battery materials: present and future. Mater. Today 18, 252–264 (2015)CrossRef
2.
J. Chen Tianmei, L. Yi, Y. Hanyu, L. Antao, C. Meiyi, X. Bing, Ying, Chen Qiang. Applications of Lithium-Ion batteries in Grid-Scale Energy Storage Systems. Trans. Tianjin Univ. 26, 208–217 (2020)CrossRef
3.
X. Li, L. Zifeng, J. Na, Y. Xiaojiao, D. Yibo, L. Li, R. Patrick, Simon Patrice, Liu Ying. Perovskite-type SrVO3 as high-performance anode materials for Lithium-ion batteries. Adv. Mater. 34, 2107262 (2021)CrossRef
4.
B. Soltani Niloofar, G. Amin, G. Lars, M. Thomas, Daria, Progress and challenges in using sustainable carbon anodes in rechargeable metal-ion batteries. Prog. Energy Combust. Sci. 87, 100929 (2021)CrossRef
5.
6.
S. Li Pengju, L. Yanglin, H. Ximing, L.X. Wenhuan, Fullerene-Intercalated Graphitic Carbon Nitride as a high-performance Anode Material for Sodium-Ion batteries. Energy Environ. Mater. 5, 608–616 (2022)CrossRef
7.
S. Perveen Tahira, S. Muhammad, I. Nadia, A. Rida, Abrar, Shahzad Muhammad Imran. Prospects in anode materials for sodium ion batteries - a review. Renew. Sustain. Energy Rev. 119, 109549 (2020)CrossRef
8.
L. Wei, S. Fei, B. Clement, Z. Hongli, J. Xiulei, H. Liangbing, Na-Ion Battery anodes: materials and Electrochemistry. Acc. Chem. Res. 49, 231–240 (2016)CrossRef
9.
Z. Chen Xinlong, Y.L. Wenjian, Z. Can, L. Sa, High-performance sodium-ion batteries with a hard carbon anode: transition from the half-cell to full-cell perspective. Nanoscale. 11, 22196–22205 (2019)CrossRefPubMed
10.
S. Tan, H. Yang, Z. Zhang, X. Xu, Y. Xu, J. Zhou, X. Zhou, Z. Pan, X. Rao, Y. Gu, Z. Wang, Y. Wu, X. Liu, Y. Zhang, The progress of hard carbon as an anode material in sodium-ion batteries. Molecules 28, 3134 (2023)CrossRefPubMedPubMedCentral
11.
Z. Sun Shijiao, C.Y. Jian, W. Huanlei, Z. Xiangyu, Resol and urea derived N-doped porous carbon for Na-ion storage. Mater. Chem. Phys. 254, 123535 (2020)CrossRef
12.
B. Escobar, D.C. Martínez-Casillas, K.Y. Pérez-Salcedo, D. Rosas, L. Morales, S.J. Liao, L.L. Huang, Shi Xuan. Research progress on biomass-derived carbon electrode materials for electrochemical energy storage and conversion technologies. Int. J. Hydrog. Energy. 46, 26053–26073 (2021)CrossRef
13.
Z. Zhao Hanqing, Y. Dan, W. Jianqi, C. Pengfei, Maosheng, Li Zhong. Directional oxygen functionalization by defect in different metamorphic-Grade coal-derived Carbon materials for Sodium Storage. Energy Environ. Mater. 5, 313–320 (2022)CrossRef
14.
C. Guo Shuai, T. Yimeng, C. Liping et al., Biomass hard carbon of high initial coulombic efficiency for sodium-ion batteries: preparation and application. Electrochimica Acta 410, 140017 (2022)CrossRef
15.
T. Mathew, X. Qingbing, H. Zhe, Z.X. Song, A review on biomass-derived hard carbon materials for sodium-ion batteries. Mater. Adv. 2, 5881–5905 (2021)CrossRef
16.
Z. Nita Cristina, D.J. Biao, Matei Ghimbeu Camélia. Hard carbon derived from coconut shells, walnut shells, and corn silk biomass waste exhibiting high capacity for Na-ion batteries. J. Energy Chem. 58, 207–218 (2021)CrossRef
17.
P. Huang Tao, C. Da-chun, Zui, Xia Xiao-hong, Chen Yu-xi, Liu Hong-bo. Microstructures and electrochemical properties of coconut shell-based hard carbons as anode materials for potassium ion batteries. New Carbon Mater. 37, 1125–1132 (2022)CrossRef
18.
R. Thenappan Meenatchi, M.S. Subadevi, Hard Carbon reprising porous morphology derived from Coconut Sheath for Sodium-Ion Battery. Energies. 15, 8086 (2022)CrossRef
19.
H.-. Zhang, C. Chao, X. Hui, Yang Li-wen, Chen Jian. Hard Carbon Derived from Straw as Anode materials for sodium-ion batteries. Int. J. Electrochem. Sci. 17, 221113 (2022)CrossRef
20.
Y.-E. Zhu, G. Haichen, C.Y.-N.Y. Donghui, W. Jinping, Hard carbon derived from corn straw piths as anode materials for sodium ion batteries. Ionics 24, 1075–1081 (2018)CrossRef
21.
Q. Xu Tianyue, Z. Xuan, X. Xiang, Yongyao, Regulation of surface oxygen functional groups and pore structure of bamboo-derived hard carbon for enhanced sodium storage performance. Chem. Eng. J. 452, 139514 (2023)CrossRef
22.
J. Alvira Darío, Plant-derived hard carbon as anode for sodium-ion batteries: a comprehensive review to guide interdisciplinary research. Chem. Eng. J. 447, 137468 (2022)CrossRef
23.
A. Olajire Abass, The brewing industry and environmental challenges. J. Clean. Prod. 256, 102817 (2020)CrossRef
24.
M.S. Darlami, L. Christian, G.-U.J. Luis, C. Rosalía, C. Daniel, Balducci Andrea. Brewery waste derived activated carbon for high performance electrochemical capacitors and lithium-ion capacitors. Electrochim. Acta. 446, 142104 (2023)CrossRef
25.
M.S. Darlami, L. Christian, Gómez-Urbano Juan Luis, Carriazo Daniel, Balducci Andrea. Brewers’ spent grains-derived Carbon as Anode for Alkali Metal-Ion batteries. Energy Technol. 10, 2200379 (2022)CrossRef
26.
Raviolo, Sofía, Bracamonte María Victoria, Calderón Cecilia Andrea, Cometto Fernando Pablo, Luque Guillermina Leticia. A Green Solution to Energy Storage: brewers’ spent grains biocarbon–silica composites as high-performance Lithium-ion batteries anodes. Energy Technol. 11, 2300342 (2023)CrossRef
27.
T. Zhang Jian, M. Zhiqiang, S. Yiqian, H. Feilong, W. Jialing, T. Hao, Ling, Origin identification of the sauce-flavor chinese baijiu by organic acids, trace elements, and the stable carbon isotope ratio. J. Food Qual. 2019, 7525201 (2019)
28.
L. Xiaogang, C. Rui, Z. Zhilei, R. Qingxi, S. Caihong, L. Yu, C. Xiaonian, Mao Jian, Conversion of baijiu distillers’ grains to functional peptides: process optimization and antioxidant activity evaluation. J. Funct. Foods. 108, 105722 (2023)CrossRef
29.
W. Weppner, R.A. Huggins, Determination of the Kinetic Parameters of Mixed-Conducting Electrodes and application to the System Li3Sb. J. Electrochem. Soc. 124, 1569 (1977)ADSCrossRef
30.
Simões dos Reis, Mayandi Subramaniyam Glaydson, Cárdenas Angélica. Chandrasekar, Larsson Duarte, H. Sylvia, T. Mikael, L. Ulla, García-Alvarado. Flaviano, Facile synthesis of sustainable activated biochars with different pore structures as efficient additive-carbon-free anodes for lithium- and sodium-ion batteries. ACS Omega 7, 42570–42581 (2022)CrossRef
31.
H. Larsson Sylvia, M. Manon, T. Mikael, Application of design of experiments (DoE) for optimised production of micro- and mesoporous Norway spruce bark activated carbons. Biomass Convers. Biorefinery 13, 10113–10131 (2023)CrossRef
32.
Y. Liu Weidong, L. Juntao, Y. Shanjian, S. Weiming, Y. Yongming, Gaixiu, Zinc chloride-activated micro-mesoporous carbon material derived from energy grass and its electrocatalytic performance toward oxygen reduction reaction. J. Energy Storage. 46, 103697 (2022)CrossRef
33.
M.V. Bracamonte, G.I. Lacconi, S.E. Urreta, L. Foa Torres, E. F. on the nature of defects in Liquid-Phase Exfoliated Graphene. J. Phys. Chem. C 118, 15455–15459 (2014)CrossRef
34.
M.A. Pimenta, G. Dresselhaus, M.S. Dresselhaus, L.G. Cançado, A. Jorio, R. Saito, Studying disorder in graphite-based systems by Raman spectroscopy. Phys. Chem. Chem. Phys. 9, 1276–1290 (2007)CrossRefPubMed
35.
W. Yang Jinlin, D. Xiaowei, L. Wenrui, C. Xu, Z. Xinhang, Z. Weichao, L. Kexin, Ming, Zou Ruqiang, Loh Kian Ping, Yang Quan-Hong, Chen Wei. From Micropores to Ultra-micropores inside Hard Carbon: toward enhanced capacity in Room-/Low-Temperature sodium-ion storage. Nano-Micro Lett. 13, 98 (2021)ADSCrossRef
36.
A. Au Heather, C.S. Hande, Jensen Anders, O. Emilia, A. O’Keefe Christopher, S. Thomas, C.-R. Maria, F. Headen Thomas, P. Grey Clare, C. Qiong, D. Alan, Titirici Maria-Magdalena. A revised mechanistic model for sodium insertion in hard carbons. Energy Environ. Sci. 13, 3469–3479 (2020)CrossRef
37.
T. Zhou Siyu, P. Zheng, H. Zhiyi, Z. Yuancheng, Z. Le, X.S. Dan, T. Yougen, S. Dhmees Abdelghaffar, Wang Haiyan. Regulating closed pore structure enables significantly improved sodium storage for hard carbon pyrolyzing at relatively low temperature. SusMat. 2, 357–367 (2022)CrossRef
Metadata
Title
Chinese baijiu spent grains-based high-performance porous hard carbon for sodium-ion battery anodes
Authors
Longhan Xu
Xiaolei Li
Qiang Zhou
Xuguang An
Jing Zhang
Weitang Yao
Xiaonan Liu
Qingquan Kong
Publication date
01-02-2024
Publisher
Springer US
Published in
Journal of Materials Science: Materials in Electronics / Issue 6/2024
Print ISSN: 0957-4522
Electronic ISSN: 1573-482X
DOI
https://doi.org/10.1007/s10854-024-12209-z

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