Nguyễn Thị Thanh Chuyền Khóa luận tốt nghiệp 2009

1. 
   Nguyễn Kim Giao (2004), Hiển vi điện tử quét, truyền qua, NXB ĐHQG Hà Nội.
   
2. 
   Trần Hiệp Hải (2005), Phản ứng điện hoá và ứng dụng, NXB Giáo dục.
   
3. 
   Hoàng Nhâm (2000), Hoá vô cơ, tập 3, NXB Giáo dục.
   
4. 
   Trịnh Xuân Sén (2002), Điện hoá học, NXB Đại học Quốc Gia Hà Nội.
   

5. 
   Brian E. Conway (2003), “Electrochemical capacitors, their Nature, function, and applications”, Electrochemistry Encyclopedia.
   
6. 
   Chengjun Xu, Baohua Li, Hongda Du, Feiyu Kang, and Yuqun Zeng (2008), “Supercapacitive studies on amorphous MnO₂ in mild solutions”, Journal of Power Sources, 184, pp.691-694.
   
7. 
   D. Linden (1994), Handbook of Batteries, McGraw-Hill, New York.
   
8. 
   Daud K.Walanda, Geoffrey A.Lawrance, and Scott W.Donne (2005), “Hydrothermal MnO₂: synthesis, structure, morphology and discharge performance”, Journal of Power Sources, 139, pp.325-341.
   
9. 
   Dinesh Balachandran (2001), “First principles study of structure, defects and proton insertion in MnO₂”, Master of Science in Materials Science and Engineering.
   
10. 
    E.Beaudrouet, A. Le Gal La Salle, D. Guyomard (2009), “Nanostructured manganese dioxides: Synthesis and properties as supercapacitor electrode materials”, Electrochimica Acta, 54, pp.1240-1248.
    
11. 
    En-Hui Liu, Xiang-Yun Meng, Rui Ding, Ji-Cheng Zhou and Song-Ting Tan (2007), “Potentiodynamical co-deposited manganese oxide/carbon composite for high capacitance electrochemical capacitors”, Materials Letters, 61, pp.3486-3489.
    
12. 
    H.Yagi, T.Ichikawa, A.Hirano, N.Imanishi, S.Ogawa, and Y.Takeda (2002), “Electrode characteristics of manganese oxides prepared by reduction method”, Solid State Ionics, 154-155, pp.273-278.
    
13. 
    Jeng-Kuei Chang, Yi-Lun Chen and Wen-Ta Tsai (2004), “Effect of heat treatment on material characteristics and pseudo-capacitive properties of manganese oxide prepared by anodic deposition”, Journal of Power Sources, 135, pp.344-353.
    
14. 
    Jianbo Wu, Hui Zhang, Xiangyang Ma, Ju Li, Feng Sun, Ning Du, and Deren Yang (2006), “Synthesis and characterization of single crystalline MnOOH and MnO₂ nanorods by mean of the hydrothermal process assisted with CTAB”, Materials Letters, 60, pp.3895-3898.
    
15. 
    Kenji Okitsu, Masaki Iwantani, Ben Naizai, Rokuro Nishimura, Yasuaki Maeda (2009), “Sonochemical reduction of permanganese dioxide: The effects of H₂O₂ formed in the sonolysis of water on the rates of reduction”, Ultrasonics Sonochemistry, 16, pp.387-391.
    
16. 
    Laurie I.Hill, Alain Verbaere, and Dominique Guyomard (2003), “MnO₂ (α-, β-, γ-) compounds prepared by hydrothermal-electrochemical synthesis: characterization, morphology and lithium insertion behavior”, Journal of Power Sources, 119-121, pp.226-23.
    
17. 
    Lixia Zhang, Chengshuai Liu, Li Zhuang, Weishan Li, Shungui Zhou, and Jintao Zhang (2009), “Manganeses dioxide as an alternative cathodic catalyst to platinum in microbial fuel cells”, Biosensors and Bioelectronics.
    
18. 
    M. Askar and H. Abbas, “Chemical activated manganese dioxide for dry batteries”, Journal of Power Sources, 51, pp.319-330.
    
19. 
    Minakshi Maniekam, Pritam Singh, Touma B. Issa, Stephen Thurgate, Roland De Marco (2004), “Lithium insertion into manganese dioxide electrode in MnO₂/Zn aqueous battery, Part I; A preliminary stydy”, Journal of Power Sources, 130, pp.254-259.
    
20. 
    Mingdeng Wei, Yoshinari Konishi, Haoshen Zhou, Hideki Sugihara and Hironori Arakawa (2005), “Synthesis of single-crystal manganese dioxide nanowires by a soft chemical process”, Nanotechnology, 16, pp.245-249.
    
21. 
    P. M. Atkin (1998), Physical Chemistry, Oxford University Press, Oxford Melbourne Tokyo.
    
22. 
    Rongji Chen, Peter Zavalij, and M.Stanley Whittingham (1996), “Hydrothermal synthesis and characterization of K_xMnO₂.yH₂O”, Chemistry of Materials, 8, pp.1275-1280.
    
23. 
    Rongrong Jiang, Tao Huang, Jiali Liu, Jihua Zhuang, and Aishui Yu (2009), “A novel method to prepare nanostructured manganese dioxide and its electrochemical as a supercapacitor electrode”, Electrochimica Acta, 54, pp.3047-3052.
    
24. 
    S.Devaraj and N.Munichandraiah (2007), “Electrochemical supercapacitor studies of nanostructured α-MnO₂ synthesized by microemulsion method and the effect of annealing”, Journal of the electrochemical society, 154, pp.80-88.
    
25. 
    Thierry Brousse, Mathieu Toupin, Romain Dugas, Laurence Athouel, Olivier Crosnier, and Daniel Bélanger (2006), “Crystalline MnO₂ as possible alternatives to amorphous compounds in electrochemical supercapacitors”, Journal of The Electrochemical Society, 153, pp.2171-2180.
    
26. 
    V.Subramanian, Hongwei Zhu, and Bingqing Wei (2006), “Nanostructured MnO₂: Hydrothermal synthesis and electrochemical properties as a supercapacitor electrode material”, Journal of Power Sources, 159, pp.361-364.
    
27. 
    Wei Xiao, Hui Xia, jerry Y.H.Fuh, and Li Lu (2009), “Growth of single-crystal α-MnO₂ nanotubes prepared by a hydrothermal route and their electrochemical property”.
    
28. 
    Xueliang Li, Wenjie Li, Xiangying Chen and Chengwu Shi (2006), “Hydrothermal synthesis and characterization of orchid-like MnO₂ nanostructures”, Journal of Crystal Growth, 297, pp.387-389.
    
29. 
    Yange Zhang, Liyong Chen, Zhi Zheng, Fengling Yang (2009), “A redox-hydrothermal route to β-MnO₂ hollow octahedrons”, Solid State Sciences.
    
30. 
    Yong Cai Zhang, Tao Qiao, Xiao Ya Hu, and Wei Dong Zhou (2005), “Simple hydrothermal preparation of γ-MnOOH nanowires and their low-temperature thermal conversion to β-MnO₂ nanowires”, Journal of Crystal Growth, 280, pp.652-657.
    
31. 
    Zhiqing Zhang and Jin Mu (2007), “Hydrothermal synthesis of γ-MnOOH nanowires and α-MnO₂ sea urchin-like clusters”, Solid State Communications, 141, pp.427-430.
    

Phụ lục