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一种理想的Li离子电池负极材料需要具有较高的储Li容量和较低的体积膨胀比. 本文应用密度泛函理论研究了二维多孔石墨炔在B, N原子掺杂调控后作为Li离子电池负极材料时的储Li性能. 计算结果表明, B在石墨炔结构中的掺杂可以增强Li与石墨炔之间的吸附作用, 储Li容量可以增加到2061.62 mAh/g, 与未掺杂单层石墨炔相比增加了2.77倍. 同时, B掺杂降低了Li在垂直于石墨炔平面方向上的扩散能垒, 而面内扩散能垒提高了0.1 eV. N掺杂降低了Li与石墨炔之间的相互作用, 但增加了Li的稳定位点, 储Li容量增加到了1652.12 mAh/g, 同时, Li在石墨炔上的扩散性能大大提高, 在平面内扩散能垒降至0.37 eV, 因此N掺杂石墨炔的充放电性能得到较好提升. 因此, B, N掺杂可从不同方面提升石墨炔作为Li电池负极材料时的储Li性能. 该研究可以为开发良好的储Li负极材料提供一个良好的研究思路, 为实验工作者提供理论依据.As the economy grows and the environment deteriorates, the renewable energy is urgently needed. The advanced energy storage technology in electronic equipment, electric vehicle, smart grid, etc. becomes more significant. For example, the rechargeable batteries, hydrogen storage media, supercapacitors, the new energy storage devices have received much attention today. The anodes of the lithium ion battery (LIB), as the main body of charging and discharging, should be most important. The ideal anode material for LIBs is required to possess a higher Li capacity and a lower volume expansion. Good reversibility and high Li capacity are balanced necessarily in the electrode material. The poor cycling performance of LIB is usually due to the severe volume expansion of anode in lithiation/delithiation process. In this paper, the Li storage performance of B and N doped graphyne is explored by using the density functional theory method. The Perdew-Burke-Ernzerhof functional of the generalized gradient approximation is chosen. The calculations indicate that the doping of B atoms can enhance the adsorption strength between the Li atom and the graphyne, which can greatly increase the Li storage capacity. The Li storage capacity of B doped graphyne can reach as high as 2061.62 mAh/g, which is 2.77 times that of pristine monolayer graphyne. Meanwhile, the B doping reduces the out-plane diffusion energy barrier of Li, but increases the in-plane diffusion energy barrier slightly by 0.1 eV. On the other hand, the doping of N atoms reduces the interaction between Li and graphyne, however, the Li capacity also increases to 1652.12 mAh/g because the number of the available Li adsorption sites increases. Moreover, the doping of N atoms greatly improves the diffusion performance of Li on graphyne. The in-plane diffusion energy barrier drops to 0.37 eV, and thus the charge-discharge performance of the N doping graphyne is well improved. Therefore, the doping of B and N atoms can remarkably improve the performance of graphyne as the LIB anodes. The remarkable performance of B and N doped graphdiyne shows that it will become a promising LIB anode in the future. The present research can provide a good theoretical basis and thus conduce to guiding the developing of good Li storage materials, and can also supply strong background for experimental researches.
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Keywords:
- graphyne /
- B doped graphyne /
- N doped graphyne /
- Li storage /
- density functional theory
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图 5 一个Li位于B掺杂的石墨炔(a) H和(c) h位点时的差分电荷密度图; 一个Li位于N掺杂石墨炔(b) H和(d) h位点的差分电荷密度图; 其中差分电荷密度范围为–0.01−0.005 e/Å3, 红色表示电子积聚, 蓝色表示电子缺失
Fig. 5. Differential charge densities: One Li at (a) H and (c) h sites of the B-doped graphyne; one Li at (b) H and (d) h sites of the N doped graphyne. The range is –0.01− 0.005 e/Å3, the red area stands for electron accumulation, and the blue area stands for electron deletion.
图 8 B, N掺杂石墨炔的开路电压随储Li容量的变化, 其中橙色划线表示B掺杂石墨炔的平均开路电压, 紫色划线表示N掺杂石墨炔的平均开路电压
Fig. 8. Change curves of the open circuit voltage with the storage Li capacity for B, N doped graphyne. The orange dash line represents the average open circuit voltage of B doped graphyne, and the purple dash line represents the average open circuit voltage of N doped graphyne.
图 9 Li在B, N掺杂石墨炔上的扩散路径和对应的能量曲线图, 图中红色曲线对应path 1上的扩散能垒; 绿色曲线对应path 2上的扩散能垒; 黑色曲线对应path 3上的扩散能垒
Fig. 9. Diffusion paths of Li on B, N doped graphyne and the corresponding energy curves. The red, green, black curves in the panels corresponds to the diffusion energy barrier on path 1, 2, 3, respectively.
表 1 B, N掺杂的石墨炔的晶格常数、键长、Mulliken电荷及Eb
Table 1. Lattice constant, bond length, Mulliken charge and Eb of B, N doped graphyne.
1 B at ring 1 B at chain 1 N at ring 1 N at chain Lattice/Å 6.98 6.92 6.86 6.90 Bond length/Å B/N-C1 1.54 1.50 1.42 1.34 B/N-C2 1.50 1.36 1.34 1.18 Charge of B/N/e 0.143 0.016 –0.247 0.226 Eb/eV 7.17 7.09 6.99 7.08 -
[1] Bruce P G, Freunberger S A, Hardwick andv L J, M Tarascon J 2012 Nat. Mater. 11 19Google Scholar
[2] Zheng G, Lee S W, Liang Z, Lee H W, Yan K, Yao H, Wang H, Li W, Chu S, Cui Y 2014 Nat. Nanotechnol. 9 618Google Scholar
[3] Cheng F Y, Liang J, Tao Z L, Chen J 2011 Adv. Mater. 23 1695Google Scholar
[4] Osumi S, Saito S, Dou C, Matsuo K, Kume K, Yoshikawa H, Awaga K, Yamaguchi S 2016 Chem. Sci. 7 219Google Scholar
[5] Binitha G, Ashish A G, Ramasubramonian D, Manikandan P, Shaijumon M M 2016 Adv. Mater. Interfaces 3 1500419Google Scholar
[6] Liang X, Hart C, Pang Q, Garsuch A, Weiss T, Nazar L F 2015 Nat. Commun. 6 5682Google Scholar
[7] Liu R Z, Zhao Y H, Chu T S 2015 Chem. Commun. 51 2429Google Scholar
[8] Zhu Y, Murali S, Stoller M D, Ganesh K J, Cai W, Ferreira P J, Pirkle A, Wallace R M, Cychosz K A, Thommes M, D Su, Stach E A, Ruoff R S 2011 Science 332 1537Google Scholar
[9] Hankel M, Searles D J 2016 Phys. Chem. Chem. Phys. 18 14205Google Scholar
[10] Hwang H J, Koo J, Park M, Park N, Kwon Y, Lee H 2013 J. Phys. Chem. C 117 6919Google Scholar
[11] Eftekhari A 2017 Ener. Storage Mater. 7 157Google Scholar
[12] Jang B, Koo J, Park M, Lee H, Nam J, Kwon Y, Lee H 2013 Appl. Phys. Lett. 103 263904Google Scholar
[13] Zhang W J 2011 J. Power. Sources 196 13Google Scholar
[14] Wu H, Cui Y 2012 Nano Today 7 414Google Scholar
[15] Paraknowitsch J P, Thomas A 2013 Ener. Environ. Sci. 6 2839Google Scholar
[16] Zhu G, Lü K, Sun Q, Kawazoe Y, Jena P 2014 Comp. Mater. Sci. 81 275Google Scholar
[17] Wang X, Weng Q, Liu X, Wang X, Tang D M, Tian W, Zhang C, Yi W, Liu D, Bando Y, Golberg D 2014 Nano Lett. 14 1164
[18] Ma C, Shao X, Cao D 2012 J. Mater. Chem. 22 8911Google Scholar
[19] Veith G M, Baggetto L, Adamczyk L, Guo A B, Brown S S, Sun X G, Albert A A, Humble J R, Barnes C E, Bojdys M J, Dai S, Dudney N J 2013 Chem. Mater. 25 503Google Scholar
[20] Tian L L, W ei, X Y, Zhuang Q C, Jiang C H, Wu C, Ma G Y, Zhao X, Zong Z M, Sun S G 2014 Nanoscale 6 6075
[21] Zhang S, Du H, He J, Huang C, Liu H, Cui G, Li Y 2016 ACS Appl. Mater. Inter. 8 8467Google Scholar
[22] Yang L, Jiang S, Zhao Y, Zhu L, Chen S, Wang X, Wu Q, Ma J, Ma Y, Hu Z 2011 Angew. Chem. Int. Ed. 50 7132Google Scholar
[23] Sheng Z H, Gao H L, Bao W J, Wang F B, Xia X H 2012 J. Mater. Chem. 22 390Google Scholar
[24] Luo G, Zhao J, Wang B 2013 Compu. Mater. Sci. 68 212Google Scholar
[25] Baughman R H, Eckhardt H, Kertesz M 1987 J. Chem. Phys. 87 6687Google Scholar
[26] Li Q, Li Y, Chen Y, Wu L, Yang C, Cui X 2018 Carbon 136 248Google Scholar
[27] Bhattacharya B, Sarkar U 2016 J. Phys. Chem. C 120 26793
[28] Jafari M, Asadpour M, Majelan N A, Faghihnasiri M 2014 Comput. Mater. Sci. 82 391Google Scholar
[29] Ruiz-Puigdollers A, Gamallo P 2017 Carbon 114 301Google Scholar
[30] Becke A D 1988 Phys. Rev. A 38 3098Google Scholar
[31] Delley B 1990 J. Chem. Phys. 92 508Google Scholar
[32] Delley B 1998 Int. J. Quant. Chem. 69 423Google Scholar
[33] Perdew J P, Chevary J A, Vosko S H, Jackson K A, Pederson M R, Singh D J 1992 Phys. Rev. B 46 6671Google Scholar
[34] Perdew J P, Burke K, Ernzerhof M 1996 Phys. Rev. Lett. 77 3865Google Scholar
[35] Grimme S 2006 J. Comput. Chem. 27 1787Google Scholar
[36] Olmstead M M, Power P P, Weese K J, Doedens R J 1987 J. Am. Chem. Soc. 109 2541Google Scholar
[37] Majidi R 2013 Nano 8 1350060
[38] Merritt L L, Lanterman E 1952 Acta Crystallogr. 5 811Google Scholar
[39] Deng X Z, Zhao Q Q, Zhao Y Q, Cai M Q 2019 Curr. Appl. Phys. 19 279Google Scholar
[40] Yu Z L, Ma Q R, Liu B, Zhao Y Q, Wang L Z, Zhou H, Cai M Q 2017 J. Phys. D: Appl. Phys. 50 465101Google Scholar
[41] Zhao Y Q, Wang X, Liu B, Yu Z L, He P B, Wan Q, Yu H L 2018 Org. Electron. 53 50Google Scholar
[42] Zhao Y Q, Ma Q R, Liu B, Yu Z L, Yang J, Cai M Q 2018 Nanoscale 10 8677Google Scholar
[43] Guo Y, Cao J, Bo X, Xia Y, Jiang Y, Liu Z 2013 Compu. Mater. Sci. 68 61Google Scholar
[44] Jiang X, Arhammar C, Liu P, Zhao J, Ahuja R 2013 Sci. Rep. 3 1877Google Scholar
[45] Kittel C 1996 Introduction to Solid State Physics (7th ed.) (Singapore: Wiley) pp356−358
[46] Zhang Q, Tang C, Zhu W, Cheng C 2018 J. Phys. Chem. C 122 22838Google Scholar
[47] Zheng F, Yang Y, Chen Q 2014 Nat. Commun. 5 5261Google Scholar
[48] Mortazavi B, Shahrokhi M, Zhuang X, Rabczuk T 2018 J. Mater. Chem. A 6 11022Google Scholar
[49] Eftekhari A, Molaei F 2015 J. Power Sources 274 1306Google Scholar
[50] Eftekhari A, Molaei F 2015 J. Power Sources 274 1315Google Scholar
[51] Halgren T A, Lipscomb W N 1977 Chem. Phys. Lett. 49 225Google Scholar
[52] Henkelman G 2000 J. Chem. Phys. 113 9978Google Scholar
[53] Sun C, Searles D J 2012 J. Phys. Chem. C 116 26222Google Scholar
[54] Chan K T, Neaton J B, Cohen M L 2008 Phys. Rev. B 77 235430Google Scholar
[55] Toyoura K, Koyama Y, Kuwabara A, Oba F, Tanaka I 2008 Phys. Rev. B 78 214303Google Scholar
[56] Valencia F, Romero A H, Ancilotto F, Silvestrelli P L 2006 J. Phys. Chem. B 110 14832Google Scholar
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