Low-temperature rapid fabrication of ZnO nanowire UV sensor array by laser-induced local hydrothermal growth

Journal of Nanomaterials

Volumn 2013, Issue , 2013, Pages

  Hong, Sukjoon ^a   Yeo, Junyeob ^a   Manorotkul, Wanit ^a   Kim, Gunho ^a   Kwon, Jinhyeong ^a   An, Kunsik ^a   Ko, Seung Hwan ^a  

^a Korea Advanced Institute of Science and Technology (KAIST)   (South Korea)

Author keywords

[No Author keywords available]

Indexed keywords

DESIRED POSITION; FACILE FABRICATION; HYDROTHERMAL GROWTH; LOCALIZED TEMPERATURE; LOW TEMPERATURES; RAPID FABRICATION; UV ILLUMINATIONS; ZNO NANOWIRE ARRAYS;

NANOWIRES; ULTRAVIOLET DEVICES;

ZINC OXIDE;

EID: 84881402012     PISSN: 16874110     EISSN: 16874129     Source Type: Journal    
DOI: 10.1155/2013/246328     Document Type: Article

References (30)

1. Huang M. H., Mao S., Feick H., Yan H., Wu Y., Kind H., Weber E., Russo R., Yang P., Room-temperature ultraviolet nanowire nanolasers. Science 2001 292 5523 1897 1899 2-s2.0-0035827304 10.1126/science.1060367 (Pubitemid 32538361)
2. Kang H. W., Yeo J., Hwang J. O., Hong S., Lee P., Han S. Y., Lee J. H., Rho Y. S., Kim S. O., Ko S. H., Sung H. J., Simple ZnO nanowires patterned growth by microcontact printing for high performance field emission device. Journal of Physical Chemistry C 2011 115 23 11435 11441 2-s2.0-80055015475 10.1021/jp2019044
3. Law M., Greene L. E., Johnson J. C., Saykally R., Yang P., Nanowire dye-sensitized solar cells. Nature Materials 2005 4 6 455 459 2-s2.0-20144369634 10.1038/nmat1387 (Pubitemid 40774050)
4. Xu S., Qin Y., Xu C., Wei Y., Yang R., Wang Z. L., Self-powered nanowire devices. Nature Nanotechnology 2010 5 5 366 373 2-s2.0-77952293658 10.1038/nnano.2010.46
5. Wang X., Zhou J., Song J., Liu J., Xu N., Wang Z. L., Piezoelectric field effect transistor and nanoforce sensor based on a single ZnO nanowire. Nano Letters 2006 6 12 2768 2772 2-s2.0-33846358960 10.1021/nl061802g (Pubitemid 46129569)
6. Zhang Y., Yu K., Jiang D., Zhu Z., Geng H., Luo L., Zinc oxide nanorod and nanowire for humidity sensor. Applied Surface Science 2005 242 1-2 212 217 2-s2.0-11844263894 10.1016/j.apsusc.2004.08.013 (Pubitemid 40086060)
7. Das S. N., Kar J. P., Choi J. H., Lee T. I., Moon K. J., Myoung J. M., Fabrication and characterization of ZnO single nanowire-based hydrogen sensor. Journal of Physical Chemistry C 2010 114 3 1689 1693 2-s2.0-77249153341 10.1021/jp910515b
8. Choi A., Kim K., Jung H., Lee S. Y., ZnO nanowire biosensors for detection of biomolecular interactions in enhancement mode. Sensors and Actuators B 2010 148 2 577 582 2-s2.0-77955309391 10.1016/j.snb.2010.04.049
9. Menzel A., Subannajui K., Güder F., Moser D., Paul O., Zacharias M., Multifunctional ZnO-nanowire-based sensor. Advanced Functional Materials 2011 21 22 4342 4348 2-s2.0-81555219726 10.1002/adfm.201101549
10. Lao C. S., Park M. C., Kuang Q., Deng Y., Sood A. K., Polla D. L., Wang Z. L., Giant enhancement in UV response of ZnO nanobelts by polymer surface-functionalization. Journal of the American Chemical Society 2007 129 40 12096 12097 2-s2.0-35048841574 10.1021/ja075249w (Pubitemid 47556837)
11. Greene L. E., Law M., Goldberger J., Kim F., Johnson J. C., Zhang Y., Saykally R. J., Yang P., Low-temperature wafer-scale production of ZnO nanowire arrays. Angewandte Chemie-International Edition 2003 42 26 3031 3034 2-s2.0-0041305911 10.1002/anie.200351461 (Pubitemid 36897012)
12. Harnack O., Pacholski C., Weller H., Yasuda A., Wessels J. M., Rectifying behavior of electrically aligned ZnO nanorods. Nano Letters 2003 3 8 1097 1101 2-s2.0-0142011538 10.1021/nl034240z (Pubitemid 37289303)
13. Swanwick M. E., Pfaendler S. M. L., Akinwande A. I., Flewitt A. J., Near-ultraviolet zinc oxide nanowire sensor using low temperature hydrothermal growth. Nanotechnology 2012 23 34 344009 10.1088/0957-4484/23/34/344009
14. Liu N., Fang G., Zeng W., Zhou H., Cheng F., Zheng Q., Yuan L., Zou X., Zhao X., Direct growth of lateral ZnO nanorod UV photodetectors with schottky contact by a single-step hydrothermal reaction. ACS Applied Materials and Interfaces 2010 2 7 1973 1979 2-s2.0-78650327883 10.1021/am100277q
15. Kong Y. C., Yu D. P., Zhang B., Fang W., Feng S. Q., Ultraviolet-emitting ZnO nanowires synthesized by a physical vapor deposition approach. Applied Physics Letters 2001 78 4 407 409 2-s2.0-0000559739 10.1063/1.1342050 (Pubitemid 33629913)
16. Liao Z. M., Xu J., Zhang J. M., Yu D. P., Photovoltaic effect and charge storage in single ZnO nanowires. Applied Physics Letters 2008 93 2 3 10.1063/1.2957470 023111
17. Lee K. H., Lee S. W., Vanfleet R. R., Sigmund W., Amorphous silica nanowires grown by the vapor-solid mechanism. Chemical Physics Letters 2003 376 3-4 498 503 2-s2.0-0141673155 10.1016/S0009-2614(03)01019-4
18. Wagner R. S., Ellis W. C., Vapor-liquid-solid mechanism of single crystal growth. Applied Physics Letters 1964 4 5 89 90 2-s2.0-33751122778 10.1063/1.1753975
19. Bai S., Wu W., Qin Y., Cui N., Bayerl D. J., Wang X., High-performance integrated ZnO nanowire UV sensors on rigid and flexible substrates. Advanced Functional Materials 2011 21 23 4464 4469 2-s2.0-82555189927 10.1002/adfm.201101319
20. Greene L. E., Law M., Tan D. H., Montano M., Goldberger J., Somorjai G., Yang P., General route to vertical ZnO nanowire arrays using textured ZnO seeds. Nano Letters 2005 5 7 1231 1236 2-s2.0-23244441072 10.1021/nl050788p (Pubitemid 41089406)
21. Xu S., Wang Z. L., One-dimensional ZnO nanostructures: solution growth and functional properties. Nano Research 2011 4 11 1013 1098 2-s2.0-80955144235 10.1007/s12274-011-0160-7
22. Yeo J., Hong S., Wanit M., Kang H. W., Lee D., Grigoropoulos C. P., Sung H. J., Ko S. H., Rapid, one-step, digital selective growth of ZnO nanowires on 3D structures using laser induced hydrothermal growth. Advanced Functional Materials 2013 23 26 3316 3323 10.1002/adfm.201203863
23. Hong S., Yeo J., Manorotkul W., Kang H. W., Lee J., Han S., Rho Y., Suh Y. D., Sung H. J., Ko S. H., Digital selective growth of a ZnO nanowire array by large scale laser decomposition of zinc acetate. Nanoscale 2013 5 9 3698 3703
24. Xu C., Shin P., Cao L., Gao D., Preferential growth of long ZnO nanowire array and its application in dye-sensitized solar cells. Journal of Physical Chemistry C 2010 114 1 125 129 2-s2.0-75149156995 10.1021/jp9085415
25. Soci C., Zhang A., Xiang B., Dayeh S. A., Aplin D. P. R., Park J., Bao X. Y., Lo Y. H., Wang D., ZnO nanowire UV photodetectors with high internal gain. Nano Letters 2007 7 4 1003 1009 2-s2.0-34248140089 10.1021/nl070111x (Pubitemid 46717749)
26. Li Y., Valle F. D., Simonnet M., Yamada I., Delaunay J. J., High-performance UV detector made of ultra-long ZnO bridging nanowires. Nanotechnology 2009 20 4 2-s2.0-58149250341 10.1088/0957-4484/20/4/045501 045501
27. Ko S. H., Lee D., Kang H. W., Nam K. H., Yeo J. Y., Hong S. J., Grigoropoulos C. P., Sung H. J., Nanoforest of hydrothermally grown hierarchical ZnO nanowires for a high efficiency dye-sensitized solar cell. Nano Letters 2011 11 2 666 671 2-s2.0-79851490678 10.1021/nl1037962
28. Lao C. S., Liu J., Gao P., Zhang L., Davidovic D., Tummala R., Wang Z. L., ZnO nanobelt/nanowire schottky diodes formed by dielectrophoresis alignment across au electrodes. Nano Letters 2006 6 2 263 266 2-s2.0-33644898897 10.1021/nl052239p (Pubitemid 43382963)
29. Hu Y., Chang Y., Fei P., Snyder R. L., Wang Z. L., Designing the electric transport characteristics of ZnO micro/nanowire devices by coupling piezoelectric and photoexcitation effects. ACS Nano 2010 4 2 1234 1240 2-s2.0-77649148701 10.1021/nn901805g
30. Guo L., Zhang H., Zhao D., Li B., Zhang Z., Jiang M., Shen D., High responsivity ZnO nanowires based UV detector fabricated by the dielectrophoresis method. Sensors and Actuators B 2012 166-167 12 16 2-s2.0-84857963482 10.1016/j.snb.2011.08.049