聚酰亚胺纳米限域镁基储氢材料湿法球磨制备及性能任务书
2020-05-02 17:09:12
1. 毕业设计(论文)的内容和要求
毕业论文主要内容: 镁基储氢合金由于其理论储氢量高(mgh2为 7.6 wt.%)、资源丰富、价格低廉等优势被认为是最具潜力的储氢材料之一。
但是其动力学和热力学性能较差,制约其实际应用。
本课题组通过hcs mm法制备的镁基储氢合金具有高容量和高活性,但是仍然存在着放氢动力学和热力学较差的问题。
2. 参考文献
[1] Targets for onboard Hydrogen storage systems for Light Duty Vehicles, US DoE. http://www1. Eere.energy.gov/hydrogenandfuelcells/storage/pdfs/target_sonboard_hydro_storage_explanation.pdf. [2] Lim, K. L,H. Kazemian, et al. Solid-state Materials and Methods for Hydrogen Storage: A Critical Review [J]. Chemical Engineering Technology, 2010, 33(2): 213-226. [3] Gosalawit-Utke R, Puszkiel J, Cattaneo Alice S, et al. 2LiBH4#8211;MgH2#8211;0.13TiCl4 confined in nanoporous structure of carbon aerogel scaffold for reversible hydrogen storage[J]. Journal of Alloys and Compounds, 2014, 599: 78-86. [4] Jianguang Yuan, Yunfeng Zhu, Liquan Li. Highly efficient bimetal synergetic catalysis by a multi-wall carbon nanotube supported palladium and nickel catalyst for the hydrogen storage of magnesium hydride [J]. Chem . Commun. , 2014,50, 6641-6644. [5] Hao Gu, Yunfeng Zhu, Liquan Li. Structures and hydrogen storage properties of Mg95Ni5 composite prepared by hydriding combustion synthesis and mechanical milling [J]. Mater. Chem. Phys., 2008, 112: 218-222. [6] Li L L, Peng B, Ji W Q, Chen J. A quantum chemical study on magnesium (Mg)/magnesium #8211;hydrogen (Mg-H) nanowires [J]. Journal of Alloys and compounds, 2009, 484(1/2): 308-313. [7] 邹勇进, 向翠丽, 邱树君, 等. 纳米限域的储氢材料[J]. 化学进展, 2013,(01):115-121. [8] Weiyu Xie, Damien J. West, Yiyang Sun, et al. Role of nano in catalysis: Palladium catalyzed hydrogen desorption from nanosized magnesium hydride [J]. Nano Energy , 2013, 2, 742#8211;748 [9] Floriano R., Leiva D. R., Deledda S., et al. MgH2-based nanocomposites prepared by short-time high energy ball milling followed by cold rolling: A new processing route [J]. J. Hydrogen energy, 2014, 39, 4404-4413. [10] Tayeh Toufic, Awad Abdel Salam, Nakhl Michel, et al. Carbon-modified MgH2: Experimental and ab-initio Investigations [J]. Zeitschrift fur naturforschung section b-a journal of chemical sciences, 2014, 69, 804-810. [11] Nielsen T K, Manickam K, Hirscher M, et al. Confinement of MgH2 Nanoclusters within Nanoporous Aerogel Scaffold Materials[J]. ACS NANO, 2009, 3(11): 3521-3528. [12] 李志宝,孙立贤, 徐芬, 等. MgH2/PMMA 复合储氢材料的制备及其脱氢研究[J]. 电源技术, 2015,(08): 1668-1670. [13] Bin-Hao Chen, Chia-Hung Kuo, Jie-Ren Ku, et al. Highly improved with hydrogen storage capacity and fast kinetics in Mg-based nanocomposites by CNTs [J]. Journal of Alloys and Compounds, 2013, 568, 78#8211;83. [14] Vajo JJ. Influence of nano-confinement on the thermodynamics and dehydrogenation kinetics of metal hydrides. Current Opinion in Solid State and Materials Science, 2011, 15:52-61. [15] Claudia Zlotea, Michel Latroche. Role of nanoconfinement on hydrogen sorption properties of metal nanoparticles hybrids [J]. Colloids and Surfaces A: Physicochem. Eng. Aspects, 2013, 439, 117#8211;130. [16]Hosseini S S, Teoh M M, Tai S C. Hydrogen separation and purification in membranes of miscible polymer blends with interpenetration networks [J]. Polymer, 2008, 49: 1594-1603. [17]Hosseini Seyed Saeid, Chung Tai Shung. Carbon membranes from blends of PBI and polyimides for N2/CH4 and CO2/CH4 separation and hydrogen purification [J]. Journal of Membrane Science, 2017, 328(1-2): 174-185. [18] Fang Q, Zhuang Z, Gu S, et al. Designed synthesis of large-pore crystalline polyimide covalent organic frameworks [J]. Nature Communications, 2014, 5: 4503. [19] Lim, D.W, Yoon, J.W, et al. Magnesium Nanocrystals Embedded in a Metal#8211;Organic Framework: Hybrid Hydrogen Storage with Synergistic Effect on Physi- and Chemisorption [J]. Angewandte Chemie, 2012, 124(39): 9952-9955. [20] Marzia Pentimalli, Franco Padella, Aurelio La Barbera, et al. A metal hydride#8211;polymer composite for hydrogen storage applications [J]. Energy Conversion and Management, 2009, 50, 3140#8211;3146. [21] Y. Liu, Alexander Rzhevskii, S. Rigos a, et al. A study of Parylene coated Pd/Mg nanoblabes for reversible hydrogen storage [J]. J. Hydrogen energy, 2013, 38, 5019-5029. [22] Jeon, K. J, H. R. Moon, et al. Air-stable magnesium nanocomposites provide rapid and high-capacity hydrogen storage without using heavy-metal catalysts [J]. Nature Materials, 2011, 10(4): 286-290. [23] Jianmei Huang, Yurong Yan, Liuzhang Ouyang, et al. Increased air stability and decreased dehydrogenation temperature of LiBH4 via modification within poly(methylmethacrylate) [J]. Dalton Transactions Communication, 2014, 43, 410-413. [24] Rapee Gosal awit-Utke, Sukanya Meethom, Claudio Pistidda, et al. Destabilization of LiBH4 by nanoconfinement in PMMA-co-BM polymer matrix for reversible hydrogen storage [J]. J. Hydrogen energy, 2014, 39, 5019-5029. [25] Anne M . Rum inski, Rizia Bardhan, et al. Synergistic enhancement of hydrogen storage and air stability via Mg nanocrystal#8211;polymer interfacial interactions [J]. Energ y Environmental Science Communication, 2013, 6, 3267#8211;3271. [26]Pentimalli M, F Padella, et al. A metal hydride-polymer composite for hydrogen storage applications [J]. Energy Conversion and Management, 2009, 50(12): 3140-3146. [27] Cui J, Wang H, Sun D L, et al. Realizing nano-confinement of magnesium for hydrogen storage using vapour transport deposition[J]. Rare Metals, 2016, 35(5): 401-407. [28] Carne-Sanchez A, Imaz I, Cano-Sarabia M, et al. A spray-drying strategy for synthesis of nanoscale metal-organic frameworks and their assembly into hollow superstructures[J]. NATURE CHEMISTRY, 2013,5(3):203-211.
3. 毕业设计(论文)进程安排
2018.12.21~ 2018.12.31:中国期刊网、维普数据库,Elsevier等数据库查阅国内外相关文献; 2019.1.04 ~ 2019.1.18:完成外文文献翻译,撰写开题报告,准备开题答辩; 2019.2.25 ~ 2019.4.5:优化Mg-Ni储氢材料纳米化制备工艺,包括在Mg95Ni5湿法球磨过程中以PI为球磨助剂时添加方式及添加量的优化,溶剂种类的选择等; 2019.4.6 ~ 2019.4.21:中期检查与答辩; 2019.4.22~ 2019.5.17:采用喷雾成膜法对纳米Mg-Ni基储氢材料进行包覆限域,强化并维持纳米结构效应,考察不同喷雾压力对颗粒分散效果及聚合物膜包覆厚度、复合颗粒尺寸等的影响,阐述机理; 2019.5.18~ 2019.6.2:撰写毕业论文; 2019.6.3~ 2019.6.14:完成毕业论文及答辩; 2019.6.15~ 2019.7.12:总结、归档。
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