本文综述了不同形态的一维V2O5纳米材料(包括纳米线、纳米棒、纳米管、纳米带)的电、磁、电化学以及光学性质,及其在传感器与致动器、场效应管(FET)、金属-绝缘体-半导体(MIS)结构、Li离子电池电极、超级电化学电容器、电致变色器件、纳米光刻模板等方面的应用,并对一维V2O5纳米材料的未来发展方向进行了展望.
参考文献
| [1] | 马江虹,翟玉春,于旭光,田彦文.一维纳米材料的研究进展[J].稀有金属与硬质合金,2004(04):41-45. |
| [2] | 李莉,童茂松,翁爱华.V2O5薄膜在传感器上的研究进展[J].功能材料,2005(10):1482-1484,1488. |
| [3] | 童茂松 .薄膜气体传感器及四单元微结构气体传感器阵列的研究[D].吉林大学,2001. |
| [4] | 童茂松,戴国瑞,闫玮,高鼎三.复合钒钼酸凝胶薄膜的湿敏特性研究[J].仪器仪表学报,2001(01):45-47. |
| [5] | 李莉,童茂松,翁爱华.复合钒钼酸干凝胶薄膜湿敏特性的影响因素[J].电子元件与材料,2006(08):25-28. |
| [6] | 李莉,童茂松,翁爱华.复合钒钼酸干凝胶薄膜的制备及其湿敏特性研究[J].传感技术学报,2005(04):710-712,716. |
| [7] | 李莉,童茂松,翁爱华.复合钒钼酸干凝胶薄膜湿敏元件的复阻抗谱[J].传感器与微系统,2006(05):39-41. |
| [8] | 童茂松,戴国瑞,何秀丽,吴远大,高鼎三.TiO2/V2O5双层薄膜的TMA气敏特性研究[J].传感器技术,2000(04):5-6,10. |
| [9] | 李莉,童茂松,翁爱华.复合钒钼酸干凝胶薄膜湿敏元件的感湿机理[J].电子元件与材料,2006(06):30-32. |
| [10] | 魏任重,李凤仪,居艳.模板法合成一维纳米材料的研究进展[J].工业催化,2004(05):1-5. |
| [11] | NORDLINDER S;EDSTROM K;GUSTAFSSON T .The performance of vanadium oxide nanorolls as cathode material in a rechargeable lithium battery[J].Electrochemical and Solid-State Letters,2001,4(08):A129-A131. |
| [12] | Xiaoxia Li;Weiyang Li;Hua Ma .Electrochemical Lithium Intercalation/Deintercalation of Single-Crystalline V_2O_5 Nanowire[J].Journal of the Electrochemical Society,2007(1):A39-A42. |
| [13] | TAKAHASHI K;LIMMER S J;WANG Y et al.Synthesis and electrochemical properties of single-crystal V2O5 nanorod arrays by template-based electrodeposition[J].Journal of Physical Chemistry B,2004,108:9795-9800. |
| [14] | Takahashi K;Wang Y;Cao GZ .Growth and electrochromic properties of single-crystal V2O5 nanorod arrays[J].Applied physics letters,2005(5):3102-1-3102-3-0. |
| [15] | HULTEEN J C;MARTIN C R .A general template-based method for the preparation of nanomaterials[J].Journal of Materials Chemistry,1997,7(07):1075-1087. |
| [16] | CAO G Z .Growth of oxide nanorod arrays through sol electrophoretic deposition[J].Journal of Physical Chemistry B,2004,108:19921-19931. |
| [17] | 陈文,彭俊锋,麦立强,徐庆,朱泉峣.两种一维纳米结构钒氧化物的合成与表征[J].无机化学学报,2004(02):147-151. |
| [18] | Chen W;Mai LQ;Qi YY;Dai Y .One-dimensional nanomaterials of vanadium and molybdenum oxides[J].The journal of physics and chemistry of solids,2006(5/6):896-902. |
| [19] | Mai LQ.;Chen W.;Xu Q.;Zhu QY.;Han CH.;Peng JF. .Cost-saving synthesis of vanadium oxide nanotubes[J].Solid State Communications,2003(10):541-543. |
| [20] | CHEN Wen;MAI Li-qiang;PENG Jun-feng et al.FTIR study of vanadium oxide nanotubes from lamellar structure[J].Journal of Materials Science,2004,39:2625-2627. |
| [21] | 陈文,麦立强,徐庆,彭俊锋,朱泉峣,余华.氧化钒纳米管的自组装合成机理[J].无机材料学报,2005(01):65-70. |
| [22] | Markus Niederberger;Hans-Joachim Muhr;Frank Krumeich;Fabian Bieri;Detlef Gunther;Reinhard Nesper .Low-Cost Synthesis of Vanadium Oxide Nanotubes via Two Novel Non-Alkoxide Routes[J].Chemistry of Materials,2000(7):1995-2000. |
| [23] | 尹桂波,张幼珠.电子纺丝及其制备的纳米纤维的应用[J].合成纤维,2004(01):13-15. |
| [24] | Periasamy Viswanathamurthi;Narayan Bhattarai;Hak Yong Kim;Douk Rae Lee .Vanadium pentoxide nanofibers by electrospinning[J].Scripta materialia,2003(6):577-581. |
| [25] | Ivanovskaya VV.;Enyashin AN.;Sofronov AA.;Makurin YN.;Medvedeva NI. Ivanovskii AL. .Electronic properties of single-walled V2O5 nanotubes[J].Solid State Communications,2003(9):489-493. |
| [26] | ENYASHIN A N;IVANOVSKAYA V V;MAKURIN YU N et al.Computer modeling of electronic properties of scroll-like V2O5-based nanotubes[J].Condensed Matter,2003,8:0309179/1-0309179/6. |
| [27] | Muster J.;Krstic V.;Park JG.;Park YW.;Roth S.;Burghard M.;Kim GT. .Electrical transport through individual vanadium pentoxide nanowires[J].Advanced Materials,2000(6):420-423. |
| [28] | G(O)MEZ-NAVARRO C;DE PABLOP J;COLCHERO J.Electrical transport in vanadium pentoxide nanowires[A].Segovia:University SEK,2001:1-5. |
| [29] | VAVILOVA E;HELLMANN I;KATAEV V et al.Magnetic properties of vanadium oxide nanotubes probed by static magnetization and 51 V NMR[J].Physical Review B,2006,73:144417/1-144417/7. |
| [30] | Imada M.;Tokura Y.;Fujimori A. .Metal-insulator transitions [Review][J].Reviews of Modern Physics,1998(4 Pt.1):1039-1263. |
| [31] | Krusin-Elbaum, L;Newns, DM;Zeng, H;Derycke, V;Sun, JZ;Sandstrom, R .Room-temperature ferromagnetic nanotubes controlled by electron or hole doping[J].Nature,2004(7009):672-676. |
| [32] | Charles J. Patrissi;Charles R. Martin .Sol-gel-based template synthesis and Li-insertion rate performance of nanostructured vanadium pentoxide[J].Journal of the Electrochemical Society,1999(9):3176-3180. |
| [33] | Liu X;Taschner C;Leonhardt A;Rummeli MH;Pichler T;Gemming T;Buchner B;Knupfer M .Structural, optical, and electronic properties of vanadium oxide nanotubes[J].Physical review, B. Condensed matter and materials physics,2005(11):5407-1-5407-5-0. |
| [34] | MAI Li-qiang;CHEN Wen;YU Hua.Optical property of vanadium oxide nanotube suspensions[A].Warrendale:Materials Research Sociaty,2005 |
| [35] | J.Cao;J.Choi;J.L.Musfeldt;S.Lutta;M.S.Whittingham .Effect of sheet distance on the optical properties of vanadate nanotubes[J].Chemistry of Materials,2004(4):731-736. |
| [36] | Chen W.;Mai LP.;Peng JF.;Xu Q.;Zhu QY. .Raman spectroscopic study of vanadium oxide nanotubes[J].International Journal of Quantum Chemistry,2004(1):377-379. |
| [37] | Liu JF;Wang X;Peng Q;Li YD .Preparation and gas sensing properties of vanadium oxide nanobelts coated with semiconductor oxides[J].Sensors and Actuators, B. Chemical,2006(1):481-487. |
| [38] | Junfeng Liu;Xun Wang;Qing Peng;Yadong Li .Vanadium Pentoxide Nanobelts: Highly Selective and Stable Ethanol Sensor Materials[J].Advanced Materials,2005(6):764-767. |
| [39] | Raible I;Burghard M;Schlecht U;Yasuda A;Vossmeyer T .V2O5 nanofibres: novel gas sensors with extremely high sensitivity and selectivity to amines[J].Sensors and Actuators, B. Chemical,2005(2):730-735. |
| [40] | BAUGHMAN R H;CUI C;ZAKHIDOV A A et al.Carbon nanotube actuators[J].Science,1999,284:1340-1344. |
| [41] | Gang Gu;Michael Schmid;Po-Wen Chiu;Andrew Minett;Jerome Fraysse;Gyu-Tae Kim;Siegmar Roth;Mikhail Kozlov;Edgar Munoz;Ray H. Baughman .V_2O_5 nanofibre sheet actuators[J].Nature materials,2003(5):316-319. |
| [42] | G. T. Kim;J. Muster;V. Krstic .Field-effect transistor made of individual V_(2)O_(5) nanofibers[J].Applied physics letters,2000(14):1875-1877. |
| [43] | Sung Myung;Minbaek Lee;Gyu Tae Kim;Jeong Sook Ha;Seunghun Hong .Large-Scale 'Surface-Programmed Assembly' of Pristine Vanadium Oxide Nanowire-Based Devices[J].Advanced Materials,2005(19):2361-2364. |
| [44] | MIN M R;KIM J H;KIM E K et al.Electrical properties of V2O5 (vanadium pentoxide) nanowires[J].Journal of the Korean Physical Society,2006,49(03):1097-1100. |
| [45] | Arthur Dobley;Katana Nagala;Shoufeng Yang;Peter Y. Zavalij;M. Stanley Whittingham .Manganese Vanadium Oxide Nanotubes: Synthesis, Characterization, and Electrochemistry[J].Chemistry of Materials,2001(11):4382-4386. |
| [46] | WANG Y;TAKAHASHIL K;SHANG H.Growth and electrochemical properties of V2O5 nanotube arrays[A].Warrendale:Materials Research Sociaty,2005 |
| [47] | Bazito FFC;Torresi RM .Cathodes for lithium ion batteries: The benefits of using nanostructured materials[J].Journal of the Brazilian Chemical Society,2006(4):627-642. |
| [48] | Yu L;Zhang XG .Hydrothermal synthesis and characterization of vanadium oxide/titanate composite nanorods[J].Materials Chemistry and Physics,2004(1):168-172. |
| [49] | R. Sordan;M. Burghard;K. Kern .Removable template route to metallic nanowires and nanogaps[J].Applied physics letters,2001(13):2073-2075. |
| [50] | PARK H;PARK J;LIM A K L et al.Nanomechanical oscillations in a single-C60 transistor[J].Nature(London),2000,407:57-60. |
| [51] | M. G. Ancona;S. E. Kooi;W. Kruppa;A. W. Snow;E. E. Foos;L. J. Whitman;D. Park;L. Shirey .Patterning of Narrow Au Nanocluster Lines Using V_2O_5 Nanowire Masks and Ion-Beam Milling[J].Nano letters,2003(2):135-138. |
| [52] | Cheng KC;Chen FR;Kai JJ .V2O5 nanowires as a functional material for electrochromic device[J].Solar Energy Materials and Solar Cells: An International Journal Devoted to Photovoltaic, Photothermal, and Photochemical Solar Energy Conversion,2006(7/8):1156-1165. |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%