Dimethylamine Controlled Sol-Gel Process to Grow ZnO Nanorods

Document Type : Research Paper

Authors

Nanomaterials Research Lab, Department of Physics, Pratap College, Amalner, Maharashtra, India.

Abstract

ZnO nanorods were prepared using dimethylamine (DMA) controlled Sol-Gel process. Dimethylamine was added as an additive to control the sol-gel process for growing ZnO nanorods. DMA would exhibit stabilizing effect, promote dissolution of precursor and control the rate of sol-gel reactions because of its basic nature and significant miscibility. The Structural and microstructural properties of the powders were characterized by X-Ray Diffractometer (XRD), Field Emission Scanning Electron Microscopy (FESEM) and Transmission Electron Microscopy (TEM). FESEM and TEM analysis revealed that the ZnO powder prepared were nanorods in nature. The optical properties of powders were characterized by UV-Visible and Photoluminescence (PL) spectroscopy. The Structural, morphological, optical and photoluminescence properties of so obtained ZnO powders consisting of nanorods were studied. DMA is simple amine but found to be very effective to control the aspect ratio of nanorods. The role of DMA in growing wurtzite structured hexagonal ZnO nanorods with [0001] orientation was interpreted and growth mechanism of ZnO nanorods was explained. 

Keywords

References

1. Vajargah PH, H., Ebrahimifard R., Golobostanfard MR, Sol–gel derived ZnO thin films: Effect of amino-additives, Appl. Surf. Sci., 2013; 285P: 732-743.
2. Yan C, Xue D, Conversion of ZnO Nanorod Arrays into ZnO/ZnS Nanocable and ZnS Nanotube Arrays via an in Situ Chemistry Strategy, J.Phy. Chem. B., 2006; 110: 25850- 25855.
3. Yan C, Xue D, Electroless deposition of aligned ZnO taper-tubes in a strong acidic medium, Electrochem. Commun. 2007; 9: 1247-1251.
4. Wen B, Huang Y, Boland JJ, Controllable Growth of ZnO Nanostructures by a Simple Solvothermal Process, J. Phy. Chem. C., 2008; 112: 106-111.
5. Yin YT., Que WX, Kam CH, ZnO nanorods on ZnO seed layer derived by sol–gel process, J. Sol-Gel Sci Tech., 2010; 53: 605-612.
6. Law M, Greene LE, Johnson JC, Saykally R, Yang PD, Nanowire dye-sensitized solar cells, Nat. Mater., 2005; 4: 455–459.
7. Liang S, Sheng H, Liu Y, Hiu Z, Lu Y, Shen H, ZnO Schottky ultraviolet photodetectors, J. Cryst. Growth., 2001; 225: 110–113.
8. Saito N, Haneda H, Sekiguchi T, Ohashi N, Sakaguchi I, Koumoto K, Low-Temperature Fabrication of Light-Emitting Zinc Oxide Micropatterns Using Self-Assembled Monolayers, Adv. Mater., 2002; 14: 418–421.
9. Huang MH, Mao S, Feick H, Yan H, Wu Y, Kind H, Weber E, Russo R, Yang P, Room-Temperature Ultraviolet Nanowire Nanolasers, Science, 2001; 292: 1897–1899.
10. Koch MH, Timbrell PY, Lamb RN, The influence of film crystallinity on the coupling efficiency of ZnO optical modulator waveguides, Semicond. Sci. Tech., 1995; 10: 1523–1527.
11. Golego N, Studenikin SA, Cocivera M, Sensor Photoresponse of Thin‐Film Oxides of Zinc and Titanium to Oxygen Gas, J. Electrochem. Soc., 2000; 147: 1592–1594.
12. Ge MY, Wu HP, Niu L, Liu JF, Chen SY, Shen PY, Zeng YW, Wang YW, Zhang GQ, Jiang JZ, Nanostructured ZnO: From monodisperse nanoparticles to nanorods, J. Cryst. Growth., 2007; 305: 162-166.
13. Huang MH, Wu Y, Feick H, Tran N, Weber E, Yang P, Catalytic Growth of Zinc Oxide Nanowires by Vapor Transport, Adv. Mater., 2001; 13: 113-116.
14. Vayssieres L, Growth of Arrayed Nanorods and Nanowires of ZnO from Aqueous Solutions, Adv. Mater., 2003; 15: 464-466.
15. Pan ZW , Dai ZR , Ma Chris, Wang ZL, Molten Gallium as a Catalyst for the Large-Scale Growth of Highly Aligned Silica Nanowires, J. Am. Chem. Soc., 2002; 124: 1817-1822.
16. Ng HT, Li J, Smith MK, Nguyen P, Cassell A, Han J, Meyyappan M, Growth of epitaxial nanowires at the junctions of nanowalls, Science, 2003; 300: 1249.
17. Umar A, Kim SH, Lee YS, Nahm KS, Hahn YB, Catalyst-free large-quantity synthesis of ZnO nanorods by a vapor–solid growth mechanism: Structural and optical properties, J. Cryst. Growth., 2005; 282: 131-136.
18. Kong YC, Yu DP, Zhang B, Fang W, Feng SQ, “Ultraviolet-Emitting ZnO Nanowires Synthesized by a Physical Vapor Deposition Approach,” Appl. Phy. Lett., 2001; 78: 407- 409.
19. Lyu SC, Zhang Y, Ruh H, Lee HJ, Shim HW, Suh EK, Lee CJ, Low temperature growth and photoluminescence of well-aligned zinc oxide nanowires, J. Chem. Phys. Lett., 2002; 363: 134-138.
20. Lee DJ, Park JY, Yun YS, Hong YS, Moon JH, Lee BT, Kim SS, Comparative studies on the growth behavior of ZnO nanorods by metalorganic chemical vapor deposition depending on the type of substrates, J. Cryst. Growth., 2005; 276: 458-464.
21. Park WI, Kim DH, Jung SW, Yi GC, Metalorganic vapor-phase epitaxial growth of vertically well-aligned ZnO nanorods, Appl. Phys. Lett., 2002; 80: 4232-4234.
22. Park JY, Lee DJ, Kim SS, Size control of ZnO nanorod arrays grown by metalorganic chemical vapour deposition, Nanotech., 2005; 16: 2044-2047.
23. Li Y, Meng GW, Zhang LD, Phillip F, Ordered Semiconductor ZnO Nanowires Arrays and Their Photoluminescence Properties, Appl. Phys. Lett., 2000; 76: 2011-2013.
24. Cheng JP, Zhang XB, Tao XY, Lu HM, Luo ZQ, Liu F, Fine-Tuning the Synthesis of ZnO Nanostructures by an Alcohol Thermal Process, J. Phys. Chem. B, 2006; 110: 10348-10353.
25. Peng W, Qu S, Cong G, Wang Z, Synthesis and Structures of Morphology-Controlled ZnO Nano- and Microcrystals, Cryst. Growth. Design., 2006; 6: 1518-1522.
26. Cao HL, Qian XF, Gong Q, Du WM, Ma XD, Zhu ZK, Shape- and size-controlled synthesis of nanometre ZnO from a simple solution route at room temperature, Nanotech., 2006; 17: 3632-3636.
27. Liu RL, Xiang Q, Pan QY, Cheng ZX, Shi LY, Hydrothermal synthesis and gas sensitivity of one-dimensional zinc oxide. Chin.J. Inorg. Mater., 2006; 21: 793-796.
28. Tam KH, Cheung CK, Leung YH, Djurišić AB, Ling CC, Beling CD, Fung S., Kwok WM, Chan WK, Phillips DL, Ding L, Ge WK, Defects in ZnO Nanorods Prepared by a Hydrothermal Method, J. Phys. Chem. B., 2006; 110: 20865-20871.
29. Voggu R, Biswas K, Govindaraj A., Rao C. N. R., Use of Fluorous Chemistry in the Solubilization and Phase Transfer of Nanocrystals, Nanorods, and Nanotubes, J. Phys. Chem. B., 2006; 110: 20752-20755.
30. Tong Y, Liu Y, Dong L, Zhao D, Zhang J, Lu Y, Shen D, Fan X, Growth of ZnO Nanostructures with Different Morphologies by Using Hydrothermal Technique, J. Phys. Chem. B., 2006; 110: 20263-20267.
31. Chen Y, Kim M, Lian G, Johnson MB, Peng X, Side Reactions in Controlling the Quality, Yield, and Stability of High Quality Colloidal Nanocrystals, J. Am. Chem. Soc., 2005; 127: 13331-13337.
32. Spanhel L, Anderson MA, Semiconductor clusters in the sol-gel process: quantized aggregation, gelation, and crystal growth in concentrated zinc oxide colloids, J.Am.Chem.Soc., 1991; 113: 2826-2833.
33. Kajikawa Y, Noda S, Komiyama H, Preferred Orientation of Chemical Vapor Deposited Polycrystalline Silicon Carbide Films, Chem. Vapour Deposition, 2002; 8: 99.
34. Biroju RK, Giri PK, Dhara S, Imakita K, Fujii M, Graphene-Assisted Controlled Growth of Highly Aligned ZnO Nanorods and Nanoribbons: Growth Mechanism and Photoluminescence Properties, Appl. Mater. Interfaces, 2014; 6: 377-387.
35. Zhang Q, Liu SJ, Yu SH, Recent advances in oriented attachment growth and synthesis of functional materials: concept, evidence, mechanism, and future, J. Mater. Chem., 2009; 19: 191.
Journal of Nanostructures
Volume 8, Issue 1
January 2018
Pages 11-20

Files

Share

How to cite

Statistics