A monolayer of self-assembled silica particles can be imprinted into a silicon (Si) substrate by laser irradiation (KrF excimer laser, λ=248 nm). Periodical hemispherical cavities can be therefore created on the substrate surface. The influences of various particle sizes and laser fluence were investigated. In addition, preheating of the substrate significantly improves the performance. One-dimensional thermal calculation was employed to understand the thermal effects in this process. Three-dimensional optical simulation provided an accurate insight into the light intensity enhancement. Raman spectroscopy was used to examine the stress induced by the laser imprinting process resided in the cavity structures. Self-assembly of binary-size nanoparticles was achieved and its application on the fabrication of binary-size nanocavity arrays by laser-assisted nanoimprinting was investigated.
REFERENCES
1.
Ferrand
, P.
, Minty
, M. J.
, Egen
, M.
, Ahopelto
, J.
, Zentel
, R.
, Romanov
, S. G.
& Sotomayor Torres
, C. M.
(2003
) Micromoulding of three-dimensional photonic crystals on silicon substrates
, Nanotechnology
14
, 323
–326
.2.
Joannopoulos
, J. D.
, Villeneuve
, P. R.
& Fan
, S.
(1997
) Photonic crystals: putting a new twist on light
, Nature
386
, 143
–147
.3.
Hirayama
, H.
, Hamano
, T.
& Aoyagi
, Y.
(1996
) Novel surface emitting laser diode using photonic band-gap crystal cavity
, Appl. Phys. Lett.
69
, 791
–793
.4.
McCord
, M. A.
(1997
) Electron beam lithography for 0.13 µm manufacturing
, J. Vac. Sci. Technol. B
15
, 2125
–2129
.5.
Dial
, O.
, Cheng
, C. C.
& Scherer
, A.
(1998
) Fabrication of high-density nanostructures by electron beam lithography
, J. Vac. Sci. Technol. B
16
, 3887
–3890
.6.
Chou
, S. Y.
, Krauss
, P. R.
, Zhang
, W.
, Guo
, L.
& Zhuang
, L.
(1997
) Sub-10 nm imprint lithography and applications
, J. Vac. Sci. Technol. B
15
, 2897
–2904
.7.
Pease
, R. F. W.
(1992
) Nanolithography and its prospects as a manufacturing technology
, J. Vac. Sci. Technol. B
10
, 278
–285
.8.
Silverman
, J. P.
(1997
) X-ray lithography: Status, challenges, and outlook for 0.13 µm
, J. Vac. Sci. Technol. B
15
, 2117
–2124
.9.
Wallraff
, G. M.
& Hinsberg
, W. D.
(1999
) Lithographic Imaging Techniques for the Formation or Nanoscopic Features
, Chem. Rev.
, 99
, 1801
–1821
.10.
Ito
, T.
& Okazaki
, S.
(2000
) Pushing the limits of lithography
, Nature
406
, 1027
–1031
.11.
Haes
, A. J.
, Haynes
, C. L.
& Van Duyne
, R. P.
(2001
) Nanosphere Lithography: Self-Assembled Photonic and Magnetic Materials
, MRS Symp.
636
, D4.8.1
–D4.8.6
.12.
Stroscio
, J. A.
& Eigler
, D. M.
(1991
) Atomic and Molecular Manipulation with the Scanning Tunnelling Microscope
, Science
254
, 1319
–1326
.13.
Liu
, G. Y.
, Xu
, S.
& Qian
, Y.
(2000
) Nanofabrication of Self-Assembled Monolayers Using Scanning Probe Lithography
, Acc. Chem. Res.
33
, 457
–466
.14.
Chou
, S. Y.
, Krauss
, P. R.
, & Renstrom
, P. J.
(1996
) Imprint Lithography with 25-Nanometer Resolution
, Science
272
, 85
–87
.15.
Kamins
, T. I.
, Ohlberg
, D. A. A.
, & Williams
, R.S.
(1999
) Positioning of self-assembled, single-crystal, germanium islands by silicon nanoimprinting
, Appl. Phys. Lett.
74
, 1773
–1775
.16.
Huang
, S. M.
, Hong
, M. H.
, Lukyanchuk
, B. S.
, Zheng
, Y. W.
, Song
, W. D.
, Lu
, Y. F.
, & Chong
, T. C.
(2002
) Pulsed laser-assisted surface structuring with optical near-field enhanced effect
, J. Appl. Phys.
92
, 2495
–2500
.17.
Ng
, V.
, Lee
, Y. V.
, Chen
, B. T.
& Adeyeye
, A. O.
(2002
) Nanostructure array fabrication with temperature-controlled self-assembly techniques
, Nanotechnology
13
, 554
–558
.18.
Mosbacher
, Chaoui
, M.
, Siegel
, N.
, Dobler
, J.
, V., Solis
, J.
, Boneberg
, J.
, Afonso
, C.N.
, & Leiderer
, P.
(1999
) A Comparison of ns and ps Steam Laser Cleaning of Si Surfaces
, Appl. Phys. A: Mater. Sci. Process.
69
, S331
–S334
.19.
Burmeister
, F.
, Sch‰fle
, C.
, Keilhofer
, B.
, Bechinger
, C.
, Boneberg
, J.
, & Leiderer
, P.
(1998
) From Mesoscopic to Nanoscopic Surface Structures: Lithography with Colloid Monolayers
, Adv. Mater.
10
(6
), 495
–497
.20.
Hulteen
, J. C.
& Van Duyne
, R P.
(1995
) Nanosphere Lithography: A Materials General Fabrication Process for Periodic Particle Array Surfaces
, J. Vac. Sci. Technol. A
13
, 1553
–1558
.21.
Li
, L.P.
, Lu
, Y.F.
, Doerr
, D.W.
, Alexander
, D.R.
, Shi
, J.
& Li
, J.C.
(2004
) Fabrication of hemispherical cavity arrays on silicon substrates using laser-assisted nanoimprinting of self-assembled particles
, Nanotechnology
15
, 333
–336
.22.
Li
, L.P.
, Lu
, Y.F.
, Shi
, J.
, Doerr
, D.W.
, Alexander
, D.R.
& Zhu
, K.G.
(2003
) Fabrication of hemispherical cavity arrays on silicon substrates using laser-assisted nanoimprinting
, in Proceedings of 22nd International Congress on Applications of Lasers and Electro-Optics
, Jacksonville, Florida, USA
.23.
Hayashi
, S.
, Amamoto
, Y. K
, Sutuki
, T.
, & Hirai
, T.
(1991
) Imaging by Polystyrene Latex Particles
, J. Colloid Interface Sci.
144
, 538
–547
.24.
Lukíyanchuk
, B.S.
, Zheng
, Y.W.
& Lu
, Y.F.
(2000
) Laser cleaning of solid surface: Optical resonance and near-field effects
, Proc. SPIE
4065
, 576
–588
.25.
26.
27.
Bohren
, C.E.
& Huffman
, D.R.
(1983
) Absorption and Scattering of Light by Small Particles
, Willey
, New York
.28.
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