镁镍基合金的可控制备及其储氢性能研究任务书

 2021-10-24 15:49:24

1. 毕业设计(论文)的内容和要求

本课题从基础研究的角度出发,通过合成特殊形貌的单质镍作为沉积基体,利用氢化化学气相沉积法制备镁镍基氢化物。

通过XRD、TEM的测试表征手段对合成的沉积基体单质镍和镁镍基氢化物的物相组成和微观形貌进行表征。

使用差式扫描量热仪和多通道气体反应控制器等测试仪器对合成的镁镍基氢化物的储氢性能进行测试。

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2. 参考文献

根据毕业要求指点2.3,毕设期间要进行研究现状调查与总结,要求在开题报告及毕业设计(论文)中涉及的英文文献不少于20篇,其中近5年不少于8篇,英文文献不少于5篇。

以下是与本课题相关的部分文献列表:[1] T. Sadhasivam, H.T. Kim, S. Jung, S.H. Roh, J.H. Park, H.Y. Jung, Dimensional effects of nanostructured Mg/MgH2 for hydrogen storage applications: A review, Renew. Sust. Energ. Rev. 72 (2017) 523-534.[2] L.Z. Ouyang, Z.J. Cao, H. Wang, R.Z. Hu, M. Zhu, Application of dielectric barrier discharge plasma-assisted milling in energy storage materials - A review, Journal of Alloys and Compounds 691 (2017) 422-435.[3] T. He, P. Pachfule, H. Wu, Q. Xu, P. Chen, Hydrogen carriers, Nat. Rev. Mater. 1(12) (2016) 17.[4] N.Z.A. Khafidz, Z. Yaakob, K.L. Lim, S.N. Timmiati, The kinetics of lightweight solid-state hydrogen storage materials: A review, International Journal of Hydrogen Energy 41(30) (2016) 13131-13151.[5] A.M. Abdalla, S. Hossain, O.B. Nisfindy, A.T. Azad, M. Dawood, A.K. Azad, Hydrogen production, storage, transportation and key challenges with applications: A review, Energy Conv. Manag. 165 (2018) 602-627.[6] C.H. An, Q.B. Deng, Improvement of Hydrogen Desorption Characteristics of MgH2 With Core-shell Ni@C Composites, Molecules 23(12) (2018) 8.[7] H.W. Liu, K. Hu, D.F. Yan, R. Chen, Y.Q. Zou, H.B. Liu, S.Y. Wang, Recent Advances on Black Phosphorus for Energy Storage, Catalysis, and Sensor Applications, Adv. Mater. 30(32) (2018) 22.[8] Z. Ma, J. Zhang, Y. Zhu, H. Lin, Y. Liu, Y. Zhang, D. Zhu, L. Li, Facile Synthesis of Carbon Supported Nano-Ni Particles with Superior Catalytic Effect on Hydrogen Storage Kinetics of MgH2, ACS Applied Energy Materials 1(3) (2018) 1158-1165.[9] D. Apostolou, P. Enevoldsen, The past, present and potential of hydrogen as a multifunctional storage application for wind power, Renew. Sust. Energ. Rev. 112 (2019) 917-929.[10] G. Chen, Y. Zhang, H. Cheng, Y. Zhu, L. Li, H. Lin, Effects of two-dimension MXene Ti3C2 on hydrogen storage performances of MgH2-LiAlH4 composite, Chemical Physics 522 (2019) 178-187.[11] A. Gasnier, M. Luguet, A.G. Pereira, H. Troiani, G. Zampieri, F.C. Gennari, Entanglement of N-doped graphene in resorcinol-formaldehyde: Effect over nanoconfined LiBH4 for hydrogen storage, Carbon 147 (2019) 284-294.[12] J.C. Liu, Y.N. Liu, Z.B. Liu, Z.L. Ma, Y.J. Ding, Y.F. Zhu, Y. Zhang, J.G. Zhang, L.Q. Li, Effect of rGO supported NiCu derived from layered double hydroxide on hydrogen sorption kinetics of MgH2, Journal of Alloys and Compounds 789 (2019) 768-776.[13] M.J. Liu, X.Z. Xiao, S.C. Zhao, M. Chen, J.F. Mao, B.S. Luo, L.X. Chen, Facile synthesis of Co/Pd supported by few-walled carbon nanotubes as an efficient bidirectional catalyst for improving the low temperature hydrogen storage properties of magnesium hydride, J. Mater. Chem. A 7(10) (2019) 5277-5287.[14] M.J. Liu, X.Z. Xiao, S.C. Zhao, S. Saremi-Yarahmadi, M. Chen, J.G. Zheng, S.Q. Li, L.X. Chen, ZIF-67 derived Co@CNTs nanoparticles: Remarkably improved hydrogen storage properties of MgH2 and synergetic catalysis mechanism, International Journal of Hydrogen Energy 44(2) (2019) 1059-1069.[15] Y.N. Liu, H.G. Gao, Y.F. Zhu, S.Y. Li, J.G. Zhang, L.Q. Li, Excellent catalytic activity of a two-dimensional Nb4C3Tx (MXene) on hydrogen storage of MgH2, Appl. Surf. Sci. 493 (2019) 431-440.[16] Q. Luo, J.D. Li, B. Li, B. Liu, H.Y. Shao, Q. Li, Kinetics in Mg-based hydrogen storage materials: Enhancement and mechanism, J. Magnes. Alloy. 7(1) (2019) 58-71.[17] J.W. Makepeace, T. He, C. Weidenthaler, T.R. Jensen, F. Chang, T. Vegge, P. Ngene, Y. Kojima, P.E. de Jongh, P. Chen, W.I.F. David, Reversible ammonia-based and liquid organic hydrogen carriers for high-density hydrogen storage: Recent progress, International Journal of Hydrogen Energy 44(15) (2019) 7746-7767.[18] B.P. Tarasov, A.A. Arbuzov, S.A. Mozhzhuhin, A.A. Volodin, P.V. Fursikov, M.V. Lototskyy, V.A. Yartys, Hydrogen storage behavior of magnesium catalyzed by nickel-graphene nanocomposites, International Journal of Hydrogen Energy 44(55) (2019) 29212-29223.[19] V.A. Yartys, M.V. Lototskyy, E. Akiba, R. Albert, V.E. Antonov, J.R. Ares, M. Baricco, N. Bourgeois, C.E. Buckley, J.M.B. von Colbe, J.C. Crivello, F. Cuevas, R.V. Denys, M. Dornheim, M. Felderhoff, D.M. Grant, B.C. Hauback, T.D. Humphries, I. Jacob, T.R. Jensen, P.E. de Jongh, J.M. Joubert, M.A. Kuzovnikov, M. Latroche, M. Paskevicius, L. Pasquini, L. Popilevsky, V.M. Skripnyuk, E. Rabkin, M.V. Sofianos, A. Stuart, G. Walker, H. Wang, C.J. Webb, M. Zhu, Magnesium based materials for hydrogen based energy storage: Past, present and future, International Journal of Hydrogen Energy 44(15) (2019) 7809-7859.[20] J.G. Zhang, Y.F. Zhu, L.L. Yao, C. Xu, Y.N. Liu, L.Q. Li, State of the art multi-strategy improvement of Mg-based hydrides for hydrogen storage, Journal of Alloys and Compounds 782 (2019) 796-823.[21] Y.X. Zhao, M.Q. Gong, Y. Zhou, X.Q. Dong, J. Shen, Thermodynamics analysis of hydrogen storage based on compressed gaseous hydrogen, liquid hydrogen and cryo-compressed hydrogen, International Journal of Hydrogen Energy 44(31) (2019) 16833-16840.[22] C. Tian, H. Zhao, H.L. Sun, K.M. Xiao, P.K. Wong, Enhanced adsorption and photocatalytic activities of ultrathin graphitic carbon nitride nanosheets: Kinetics and mechanism, Chem. Eng. J. 381 (2020) 10.

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