1. 毕业设计（论文）的内容和要求

1. 毕业设计的内容 如今，能源转型正在世界各国陆续开展。

而可再生能源由于其不稳定和不连续等因素需要配备储能装置。

近几十年来，锂离子电池由于其高能量密度占据了电池的大部分市场。

2. 参考文献

[1] W. Tang, J. Xuan, H. Wang, S. Zhao, H. Liu, First-principles investigation of aluminum intercalation and diffusion in TiO2 materials: Anatase versus rutile, Journal of Power Sources, 384 (2018) 249-255. [2] T. Li, U. Gulzar, X. Bai, S. Monaco, G. Longoni, M. Prato, S. Marra, Z. Dang, C. Capiglia, R.P. Zaccaria, Surface and interface engineering of anatase TiO2 anode for sodium-ion batteries through Al2O3 surface modification and wise electrolyte selection, Journal of Power Sources, 384 (2018) 18-26. [3] H. Lahan, S.K. Das, An approach to improve the Al3 ion intercalation in anatase TiO2 nanoparticle for aqueous aluminum-ion battery, Ionics, 24 (2018) 1855-1860. [4] M. Kazazi, Z.A. Zafar, M. Delshad, J. Cervenka, C. Chen, TiO2/CNT nanocomposite as an improved anode material for aqueous rechargeable aluminum batteries, Solid State Ionics, 320 (2018) 64-69. [5] A. Holland, R. McKerracher, A. Cruden, R. Wills, Electrochemically Treated TiO2 for Enhanced Performance in Aqueous Al-Ion Batteries, Materials (Basel, Switzerland), 11 (2018). [6] H. Lahan, R. Boruah, A. Hazarika, S.K. Das, Anatase TiO2 as an Anode Material for Rechargeable Aqueous Aluminum-Ion Batteries: Remarkable Graphene Induced Aluminum Ion Storage Phenomenon, Journal of Physical Chemistry C, 121 (2017) 26241-26249. [7] T. Koketsu, J. Ma, B.J. Morgan, M. Body, C. Legein, W. Dachraoui, M. Giannini, A. Demortiere, M. Salanne, F. Dardoize, H. Groult, O.J. Borkiewicz, K. Chapman, P. Strasser, D. Dambournet, Reversible magnesium and aluminium ions insertion in cation-deficient anatase TiO2, Nature Materials, 16 (2017) 1142. [8] M. Kazazi, P. Abdollahi, M. Mirzaei-Moghadam, High surface area TiO2 nanospheres as a high-rate anode material for aqueous aluminium-ion batteries, Solid State Ionics, 300 (2017) 32-37. [9] L. Jiang, J. Qi, Y. Sui, X. Liu, Y. He, Q. Meng, F. Wei, Z. Sun, Y. Jin, Preparation and capacitance properties of Al-doped hierarchical TiO2 nanostructure by oxidation of Ti-8Al alloy, Journal of Materials Science-Materials in Electronics, 28 (2017) 13770-13779. [10] S. Sang, Y. Liu, W. Zhong, K. Lui, H. Liu, Q. Wu, The electrochemical behavior of TiO2-NTAs electrode in H and Al3 coexistent aqueous solution, Electrochimica Acta, 187 (2016) 92-97. [11] Y. Liu, S. Sang, Q. Wu, Z. Lu, K. Liu, H. Liu, The electrochemical behavior of Cl- assisted Al3 insertion into titanium dioxide nanotube arrays in aqueous solution for aluminum ion batteries, Electrochimica Acta, 143 (2014) 340-346. [12] Y.J. He, J.F. Peng, W. Chu, Y.Z. Li, D.G. Tong, Black mesoporous anatase TiO2 nanoleaves: a high capacity and high rate anode for aqueous Al-ion batteries, Journal of Materials Chemistry A, 2 (2014) 1721-1731. [13] Y. Zhang, S. Liu, Y. Ji, J. Ma, H. Yu, Emerging Nonaqueous Aluminum-Ion Batteries: Challenges, Status, and Perspectives, Advanced Materials, 30 (2018). [14] Z.A. Zafar, S. Imtiaz, R. Razaq, S. Ji, T. Huang, Z. Zhang, Y. Huang, J.A. Anderson, Cathode materials for rechargeable aluminum batteries: current status and progress, Journal of Materials Chemistry A, 5 (2017) 5646-5660. [15] G.A. Elia, K. Marquardt, K. Hoeppner, S. Fantini, R. Lin, E. Knipping, W. Peters, J.-F. Drillet, S. Passerini, R. Hahn, An Overview and Future Perspectives of Aluminum Batteries, Advanced Materials, 28 (2016) 7564-7579.

3. 毕业设计（论文）进程安排

2019.02.26-2019.03.10 查阅文献资料，了解研究背景，完成外文翻译，文献综述和开题报告 2019.3.11-2019.5.16 进行课题实验，结果分析与处理 2019.05.17-2019.06.07 撰写毕业论文，完成审阅与修改 2019.06.07-2019.06.10 制作答辩PPT，进行答辩