Nano

Lett 2009, 9:279–282 CrossRef 4 Lin CX, Povinelli M

Nano

Lett 2009, 9:279–282.CrossRef 4. Lin CX, Povinelli ML: Optical absorption enhancement in silicon nanowire arrays with a large lattice constant for photovoltaic applications. Opt Express 2009, 17:19371–19381.CrossRef 5. Tsakalakos L, Balch J, Fronheiser J, Shih MY, LeBoeuf SF, Pietrzykowski M, Cordella P, Korevaar B, Sulima O, Rand J, Davuluru A, Rapol U: Strong broadband optical absorption in silicon nanowire films. J Nanophotonics 2007, 1:013552.CrossRef 6. Kosten ED, Warren EL, Atwater HA: Ray optical light trapping Adriamycin in silicon microwires: exceeding the 2n(2) intensity limit. Opt Express 2011, 19:3316–3331.CrossRef 7. Zhang ML, Peng KQ, Fan X, Jie JS, Zhang RQ, Lee ST, Wong NB: Preparation of large-area uniform silicon nanowires arrays through metal-assisted chemical etching. J Phys Chem C 2008, 112:4444–4450.CrossRef 8. Li XL: Metal assisted chemical etching for high aspect ratio nanostructures: a review of characteristics and applications in photovoltaics. Current Opinion in Solid State & Mater Sci 2012, 16:71–81.CrossRef 9. Shin JC, Zhang C, Li XL: Sub-100 nm Si nanowire and nano-sheet array formation by MacEtch using a non-lithographic InAs nanowire mask. Nanotechnology 2012, 23:305305.CrossRef 10. Hochbaum AI, Fan R, He RR, Yang PD: Controlled growth of Si nanowire arrays for device integration.

Nano Lett 2005, see more 5:457–460.CrossRef 11. Zhang YF, Tang YH, Wang N, Yu DP, Lee CS, Bello I, Lee ST: Silicon nanowires prepared by laser ablation at high temperature. Appl Phys Lett 1998, 72:1835–1837.CrossRef 12. Pan H, Lim S, Poh C, Sun H, Wu X, Feng Y, Lin J: Growth of Si nanowires by thermal evaporation. Nanotechnology 2005, 16:417–421.CrossRef 13. Liu HI, Maluf NI, Pease RFW, Biegelsen DK, Johnson NM, Ponce FA: Oxidation of sub-50 Nm Si columns for light-emission study. J Vac Sci Technol B 1992, 10:2846–2850.CrossRef 14. Chen C, Jia R, Yue HH, Li HF, Liu XY, Wu DQ, Ding WC, Ye T, Kasai S, Tamotsu H, Chu J,

Wang S: Silicon nanowire-array-textured solar cells for photovoltaic application. J Appl Phys 2010, 108:094318.CrossRef 15. Shiu SC, Chao JJ, Hung SC, Yeh CL, Lin CF: Morphology SC75741 chemical structure dependence of silicon nanowire/poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) for heterojunction solar cells. Chem Mater 2010, 22:3108–3113.CrossRef 16. Kayes BM, Atwater HA, Lewis NS: Comparison of the device physics principles of planar and radial p-n junction nanorod solar cells. J Appl Phys 2005, 97:114302.CrossRef 17. Stelzner T, Pietsch M, Andra G, Falk F, Ose E, Christiansen S: Silicon nanowire-based solar cells. Nanotechnology 2008, 19:295203.CrossRef 18. Sivakov V, Andra G, Gawlik A, Berger A, Plentz J, Falk F, Christiansen SH: Silicon nanowire-based solar cells on glass: synthesis, optical properties, and cell parameters. Nano Lett 2009, 9:1549–1554.CrossRef 19.

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