Strain effects in a single ZnO microwire with wavy configurations

Nanotechnology

Volumn 24, Issue 45, 2013, Pages

  Park, Jong Bae ^a,b   Hong, Woong Ki ^a   Bae, Tae Sung ^a   Sohn, Jung Inn ^b   Cha, Seungnam ^b   Kim, Jong Min ^b   Yoon, Jongwon ^c   Lee, Takhee ^d  

^a Korea Basic Science Institute (KBSI)   (South Korea)

^b UNIVERSITY OF OXFORD   (United Kingdom)

^c Gwangju Institute of Science and Technology (GIST)   (South Korea)

^d Seoul National University   (South Korea)

Author keywords

[No Author keywords available]

Indexed keywords

BENDING STRAIN; CATHODOLUMINESCENCE SPECTRA; GEOMETRIC MODELING; MECHANICAL STRAIN; NEAR BAND EDGE EMISSIONS; STRAIN EFFECT; STRAIN-DEPENDENT; WAVY GEOMETRY;

BAND STRUCTURE; LASER RADIATION; ZINC OXIDE;

STRAIN;

EID: 84886263311     PISSN: 09574484     EISSN: 13616528     Source Type: Journal    
DOI: 10.1088/0957-4484/24/45/455703     Document Type: Article

References (28)

1. Chen J, Conache G, Pistol M-E, Gray S M, Borgström M T, Xu H, Xu H Q, Samuelson L and Håkanson U 2010 Probing strain in bent semiconductor nanowires with Raman spectroscopy Nano Lett. 10 1280-6
2. Cao J et al 2009 Strain engineering and one-dimensional organization of metal-insulator domains in single-crystal vanadium dioxide beams Nature Nanotechnol. 4 732-7
3. Han X et al 2009 Electronic and mechanical coupling in bent ZnO nanowires Adv. Mater. 21 4937-41
4. Han X, Kou L, Zhang Z, Zhang Z, Zhu X, Xu J, Liao Z, Guo W and Yu D 2012 Strain-gradient effect on energy bands in bent ZnO microwires Adv. Mater. 24 4707-11
5. Han X, Jing G, Zhang X, Ma R, Song X, Xu J, Liao Z, Wang N and Yu D 2009 Bending-induced conductance increase in individual semiconductor nanowire and nanobelts Nano Res. 2 553-7
6. Wei B, Zheng K, Ji Y, Zhang Y, Zhang Z and Han X 2012 Size-dependent bandgap modulation of ZnO nanowires by tensile strain Nano Lett. 12 4595-9
7. Liao Z-M et al 2012 Strain induced exciton fine-structure splitting and shift in bent ZnO Sci. Rep. 2 452
8. Dietrich C P, Lange M, Klüpfel F J, Wenckstern H v, Schmidt-Grund R and Grundman M 2011 Strain distribution in bent ZnO microwires Appl. Phys. Lett. 98 031105
9. Yan B, Chen R, Zhou W, Zhang J, Sun H, Gong H and Yu T 2010 Localized suppression of longitudinal-optical-phonon-exciton coupling in bent ZnO nanowires Nanotechnology 21 445706
10. Guo W, Yang Y, Liu J and Zhang Y 2010 Tuning of electronic transport characterization of ZnO micro/nanowire piezotronic Schottky diodes by bending: threshold voltage shift 2010 Phys. Chem. Chem. Phys. 12 14868-72
11. Gao Y and Wang Z L 2007 Elecctrostatic potential in a bent piezoelectric nanowire. The fundamental theory of nanogenerator and nanopiezotronics Nano Lett. 7 2499-505 (Pubitemid 47310152)
12. Wang Z L 2007 Nanopiezotronics Adv. Mater. 19 889-92 (Pubitemid 46932825)
13. Wang X, Song J, Liu J and Wang Z L 2007 Direct-current nanogenerator driven by ultrasonic waves Science 316 102-5 (Pubitemid 46559527)
14. Rogers J A, Someya T and Huang Y 2010 Materials and mechanics for stretchable electronics Science 327 1603-7
15. Hong W-K et al 2008 Tunable electronic transport characteristics of surface-architecture-controlled ZnO nanowire field effect transistors Nano Lett. 8 950-6
16. Pan Z W, Dai Z R and Wang Z L 2001 Nanobelts of semiconducting oxides Science 291 1947-9 (Pubitemid 32216991)
17. Hu Y, Chang Y, Fei P, Snyder R L and Wang Z L 2010 Desinging the electric transport characteristics of ZnO micro/nanowire devices by coupling piezoelectric and photoexcitation effects ACS Nano 4 1231-40
18. Fan Z, Ho J C, Jacobson Z A, Yerushalmi R, Alley R L, Razavi H and Javey A 2008 Wafer-scale assembly of highly ordered semiconductor nanowire arrays by contact printing Nano Lett. 8 20-5 (Pubitemid 351177769)
19. Shalish I, Temkin H and Narayanamurti V 2004 Size-dependent surface luminescence in ZnO nanowires Phys. Rev. B 69 245401
20. Djurišić A B, Choy W C H, Roy V A L, Leung Y H, Kwong C Y, Cheah K W, Rao T K G, Chan W K, Lui H F and Surya C 2004 Photoluminescence and electron paramagnetic resonance of ZnO tetrapod structure Adv. Funct. Mater. 14 856-64
21. Zhou X, Kuang Q, Jiang Z-Y, Xie Z-X, Xu T, Huang R-B and Zheng L-S 2007 The origin of green emission of ZnO microcrystallites: surface-dependent light emission studied by cathodoluminescence J. Phys. Chem. C 111 12091-3 (Pubitemid 47325792)
22. Ryu S Y, Xiao J, Park W I, Son K S, Huang Y Y, Paik U and Rogers J A 2009 Lateral buckling mechanics in silicon nanowires on elastomeric substrates Nano Lett. 9 3214-9
23. Feng X, Yang B D, Liu Y, Wang Y, Dagdeviren C, Liu Z, Carlson A, Li J, Huang Y and Rogers J A 2011 Stretchable ferroelectric nanoribbons with wavy configurations on elastomeric substrates ACS Nano 5 3326-32
24. Xu F, Lu W and Zhu Y 2011 Controlled 3D buckling of silicon nanowires for stretchable electronics ACS Nano 5 672-8
25. Xue H, Pan N, Li M, Wu Y, Wang X and Hou J G 2010 Probing the strain effect on near band edge emission of a curved ZnO nanowire via spatially resolved cathodoluminescence Nanotechnology 21 215701
26. Xu S, Guo W, Du S, Loy M M T and Wang N 2012 Piezotronic effects on the optical properties of ZnO nanowires Nano Lett. 12 5802
27. Kou L, Li C, Zhang Z-Y, Chen C and Guo W 2010 Charge carrier separation induced by intrinsic surface strain in pristine ZnO nanowires Appl. Phys. Lett. 97 053104
28. Li Y F et al 2008 Biaxial stress-dependent optical band gap, crystalline, and electronic structure in wurtzite ZnO: experimental and ab initio study J. Appl. Phys. 104 083516