Hydrothermal deposition and characterization of silicon oxide nanospheres

Materials Characterization

Volumn 59, Issue 5, 2008, Pages 656-659

  Pei, L Z ^a  

^a ANHUI UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

Hydrothermal deposition; Photoluminescence; Silicon oxide nanospheres

Indexed keywords

ENERGY DISPERSIVE X RAY ANALYSIS; PARTICLE SIZE; PHOTOLUMINESCENCE; SCANNING ELECTRON MICROSCOPY; SILICA; TRANSMISSION ELECTRON MICROSCOPY;

AMORPHOUS STRUCTURE; BLUE LIGHT EMISSION; HYDROTHERMAL DEPOSITION; SILICON OXIDE NANOSPHERES;

NANOSPHERES;

EID: 40649122225     PISSN: 10445803     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.matchar.2007.04.011     Document Type: Article

References (24)

1. Caruso F., Caruso R.A., and Möhwald H. Nanoengineering of inorganic and hybrid hollow spheres by colloidal templating. Science 282 (1998) 1111-1114
2. Göltner C.G. Porous solids from rigid colloidal templates: morphogenesis. Angew Chem Int Ed 38 (1999) 3155-3156
3. Sun Y., and Xia Y. Shape-controlled synthesis of gold and silver nanoparticles. Science 298 (2002) 2176-2179
4. Sun Y., Mayers B., and Xia Y. Metal nanostructures with hollow interiors. Adv Mater 15 (2003) 641-646
5. Morales A.M., and Lieber C.M. A laser ablation method for the synthesis of crystalline semiconductor nanowires. Science 279 (1998) 208-211
6. Tang Y.H., Pei L.Z., Chen Y.W., and Guo C. Self-assembled silicon nanotubes under supercritically hydrothermal conditions. Phys Rev Lett 95 (2005) 116102
7. x nanowires. Mater Lett 60 (2006) 150-153
8. He J.Z., Xu J.B., Xie Z., Chiah M.F., Ke N., Cheung W.Y., et al. Sample refinement and manipulation of silicon nanowires: a step towards single wire characterization. Mater Charact 48 (2002) 177-181
9. Scholz S.M., Vacassy R., Dutta J., and Hofmann H. Mie scattering effects from monodispersed ZnS nanospheres. J Appl Phys 83 (1998) 7860-7866
10. Gao S.M., Xie Y., Lu J., Du G.A., He W., Cui D.L., et al. Mild benzene-thermal route to GaP nanorods and nanospheres. Inorg Chem 41 (2002) 1850-1854
11. Hu Y., Chen J.F., Chen W.M., and Ning J.Q. Preparation of hollow CdSe nanospheres. Mater Lett 58 (2004) 2911-2913
12. Shen G.Z., Chen D., Liu Y.F., Tang K.B., and Qian Y.T. Synthesis of ZrC hollow nanospheres at low temperature. J Cryst Growth 262 (2004) 277-280
13. 3 nanosphere and nanorods. Mater Lett 59 (2005) 319-321
14. 2 nanospheres via ostwald ripening. J Phys Chem B 108 (2004) 3492-3495
15. 2 nanospheres. Mater Lett 54 (2002) 85-88
16. Gole J.L., Stout J.D., Rauch W.L., and Wang Z.L. Direct synthesis of silicon nanowires, silica nanospheres, and wire-like nanosphere agglomerates. Appl Phys Lett 76 (2000) 2346-2348
17. Gao R.P., Wang Z.L., Stout J.W., and Gole J.L. Silica nanotubes and nanofiber arrays. Adv Mater 12 (2000) 1938-1940
18. 2 nanospheres. Langmuir 13 (1997) 6009-6011
19. Lecren L., Toupance T., and Backov R. Synthesis and characterization of multi-wall silica nanospheres. Mater Lett 59 (2005) 817-820
20. 2 nanospheres by hydrothermal reaction. Mater Lett 60 (2006) 527-529
21. Pei L.Z., Tang Y.H., Chen Y.W., Guo C., Zhang W., and Zhang Y. Silicon nanowires grown from silicon monoxide under hydrothermal conditions. J Cryst Growth 289 (2006) 423-427
22. Gogotsi Y., Libera J.A., and Yoshimura M. Hydrothermal synthesis of multiwall carbon nanotubes. J Mater Res 15 (2000) 2591-2594
23. Yu D.P., Hang Q.L., Ding Y., Zhang H.Z., Bai Z.G., Wang J.J., et al. Amorphous silica nanowires: intensive blue light emitters. Appl Phys Lett 73 (1998) 3076-3078
24. Zhang Y.F., Tang Y.H., Wang N., Lee C.S., Bello I., and Lee S.T. One-dimensional growth mechanism of crystalline silicon nanowires. J Cryst Growth 197 (1999) 136-140