参考文献
| [1] | Gubbala S,Thangala J,Sunkara M K.Nanowire-based electrochromic devices.Sol Energy Mater Sol Cells,2007,91 (9):813 |
| [2] | Reyes L F,Hoel A.Gas sensor response of pure and activated WO3 nanoparticle films made by advanced reactive gas deposition.Sens Actuators B,2006,117(1):128 |
| [3] | Cao B,Chen J,Tang X,et al.Growth of monoclinic WO3 nanowire array for highly sensitive NO2 detection.J Mater Chem,2009,19:2323 |
| [4] | Pan Z W,Dai Z R,Wang Z L.Nanobelts of semiconducting oxides.Science,2001,291:1947 |
| [5] | Baek Y,Yong K.Controlled growth and characterization of tungsten oxide nanowires using thermal evaporation of WO3 powder.J Phys Chem C,2007,111:1213 |
| [6] | Sun S,Zhao Y,Xia Y,et al.Bundled tungsten oxide nanowires under thermal processing.Nanotechnology,2008,19:305709 |
| [7] | Li Lezhong,Yang Weiqing,Ding Yingchun,et al.First principle study of the electronic structure of hafnium-doped anatase TiO2.Journal of Semiconductors,2012,33(1):012002 |
| [8] | Gao Pan,Zhang Xuejun,Zhou Wenfang,et al.First-principle study on anatase TiO2 codoped with nitrogen and ytterbium.Journal of Semiconductors,2010,31 (3):032001 |
| [9] | Si Panpan,Su Xiyu,Hou Qinying,et al.First-principles calculation of the electronic band of ZnO doped with C.Journal of Semiconductors,2009,30(5):052001 |
| [10] | Yakovkin I N,Gutowski M.Driving force for the WO3 (001) surface relaxation.Surf Sci,2007,601(6):1481 |
| [11] | Wang F,Valentin C D,Pacchioni G.electronic and structural properties ofWO3∶ a systematic hybrid DFT study.J Phys Chem C,2011,115:8345 |
| [12] | Cao B,Chen J,Tang X,et al.Growth of monoclinic WO3 nanowire array for highly sensitive NO2 detection.J Mater Chem,2009,19(16):2323 |
| [13] | Song X,Zheng Y,Yang E,et al.Large-scale hydrothermal synthesis of WO3 nanowires in the presence of K2SO4.Mater Lett,2007,61:3904 |
| [14] | Loopstra B O,Boldrini P.Neutron diffraction investigation of WO3.Acta Crystallogr B,1966,21:158 |
| [15] | Gao M,You S,Wang Y.First-principles study of silicon nanowires with different surfaces.Jpn J Appl Phys,2008,47:3303 |
| [16] | Zhang F C,Zhang Z Y,Zhang W H,et al.First-principles study of the electronic and optical properties of ZnO nanowires.Chin Phys B,2009,18:2508 |
| [17] | Li Y,Zhou Z,Chen Y,et al.Do all wurtzite nanotubes prefer faceted ones.J Chem Phys,2009,130:204706 |
| [18] | Vo T,Williamson A J,Galli G.First principles simulations of the structural and electronic properties of silicon nanowires.Phys Rev B,2006,74(4):045116 |
| [19] | Hu W,Zhao Y,Liu Z,et al.Nanostructural evolution:from onedimensional tungsten oxide nanowires to three-dimensional ferberite flowers.Chem Mater,2008,20:5657 |
| [20] | Gillet M,Aguir K,Lemire C,et al.The structure and electrical conductivity of vacuum-annealed WO3 thin films.Thin Solid Films,2004,467:239 |
| [21] | Filippi C,Singh D J,Umrigar C J.All-electron local-density and generalized-gradient calculations of the structural properties of semiconductors.Phys Rev B,1994,50(20):14947 |
| [22] | Zhao X,Wei C M,Yang L,et al.Quantum confinement and electronic properties of silicon nanowires.Phys Rev Lett,2004,92(23):236805 |
| [23] | May R A,Kondrachova L,Hahn B P,et al.Optical constants of electrodeposited mixed molybdenum-tungsten oxide films determined by variable-angle spectroscopic ellipsometry.J Phys Chem C,2007,111(49):18251 |
| [24] | Zheng H,Ou J Z,Strano M S,et al.Nanostructured tungsten oxide properties,synthesis,and applications.Adv Funct Mater,2011,21:2175 |
| [25] | Zhou Z,Zhao J,Chen Y,et al.Energetics and electronic structures of A1N nanotubes/wires and theft potential application as ammonia sensors.Nanotechnology,2007,18:424023 |
| [26] | Jones F H,Rawlings K,Foord J S,et al.Superstructures and defect structures revealed by atomic-scale STM imaging of WO3 (001).Phys Rev B,1995,52(20):14392 |
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%