Optical response from lenslike semiconductor nipple arrays

被引：21

作者：

Wu, H-M. ^{[1
,2
]}

Lai, C-M. ^{[3
]}

Peng, L-H. ^{[1
,2
]}

机构：

[1] Natl Taiwan Univ, Dept Elect Engn, Taipei 106, Taiwan

[2] Natl Taiwan Univ, Inst Photon & Optoelect, Taipei 106, Taiwan

[3] Ming Chuan Univ, Dept Elect Engn, Tao Yuan 333, Taiwan

来源：

APPLIED PHYSICS LETTERS | 2008年 / 93卷 / 21期

关键词：

arrays; elemental semiconductors; etching; gallium compounds; III-V semiconductors; masks; monolayers; polymers; reflectivity; self-assembly; silicon; visible spectra; wide band gap semiconductors;

D O I：

10.1063/1.3036629

中图分类号：

O59 [应用物理学];

学科分类号：

摘要：

The authors reported the use of recessive size reduction in self-assembled polystyrene sphere mask with anisotropic etching to form lenslike nipple arrays onto the surface of silicon and gallium nitride. These devices are shown to exhibit a filling factor near to an ideal close-packed condition and paraboloidlike etch profile with slope increased proportionally to the device aspect ratio. Specular reflectivity of less than 3% was observed over the visible spectral range for the 0.35-mu m-period nipple-lens arrays. Using two-dimensional rigorous coupled-wave analysis, the latter phenomenon can be ascribed to a gradual index matching mechanism accessed by a high surface-coverage semiconductor nipple array structure.

引用

页数：3

共 18 条

[1] Calcitic microlenses as part of the photoreceptor system in brittlestars [J].

Aizenberg, J ;

Tkachenko, A ;

Weiner, S ;

Addadi, L ;

Hendler, G .

NATURE, 2001, 412 (6849) :819-822

[2] A conceptual model of light coupling by pillar diffraction gratings [J].

Catchpole, K. R. ;

Green, M. A. .

JOURNAL OF APPLIED PHYSICS, 2007, 101 (06)

[3] Using colloidal lithography to fabricate and optimize sub-wavelength pyramidal and honeycomb structures in solar cells [J].

Chen, H. L. ;

Chuang, S. Y. ;

Lin, C. H. ;

Lin, Y. H. .

OPTICS EXPRESS, 2007, 15 (22) :14793-14803

[4] Light in tiny holes [J].

Genet, C. ;

Ebbesen, T. W. .

NATURE, 2007, 445 (7123) :39-46

[5] Reflection properties of nanostructure-arrayed silicon surfaces [J].

Hadobás, K ;

Kirsch, S ;

Carl, A ;

Acet, M ;

Wassermann, EF .

NANOTECHNOLOGY, 2000, 11 (03) :161-164

[6] Nanosphere lithography: Size-tunable silver nanoparticle and surface cluster arrays [J].

Hulteen, JC ;

Treichel, DA ;

Smith, MT ;

Duval, ML ;

Jensen, TR ;

Van Duyne, RP .

JOURNAL OF PHYSICAL CHEMISTRY B, 1999, 103 (19) :3854-3863

[7] Light extraction simulation of surface-textured light-emitting diodes by finite-difference time-domain method and ray-tracing method [J].

Kawaguchi, Yoshiyuki ;

Nishizono, Kazuhiro ;

Lee, Jeong-Sik ;

Katsuda, Hirohiko .

JAPANESE JOURNAL OF APPLIED PHYSICS PART 1-REGULAR PAPERS BRIEF COMMUNICATIONS & REVIEW PAPERS, 2007, 46 (01) :31-34

[8] Mass transport: semiconductor microstructure fabrication by surface energy [J].

Liau, ZL .

MATERIALS SCIENCE & ENGINEERING R-REPORTS, 2003, 42 (02) :41-63

[9] STABLE IMPLEMENTATION OF THE RIGOROUS COUPLED-WAVE ANALYSIS FOR SURFACE-RELIEF GRATINGS - ENHANCED TRANSMITTANCE MATRIX APPROACH [J].

MOHARAM, MG ;

POMMET, DA ;

GRANN, EB ;

GAYLORD, TK .

JOURNAL OF THE OPTICAL SOCIETY OF AMERICA A-OPTICS IMAGE SCIENCE AND VISION, 1995, 12 (05) :1077-1086

[10] High fidelity fabrication of microlens arrays by nanoimprint using conformal mold duplication and low-pressure liquid material curing [J].

Peng, Can ;

Liang, Xiaogan ;

Fu, Zengli ;

Chou, Stephen Y. .

JOURNAL OF VACUUM SCIENCE & TECHNOLOGY B, 2007, 25 (02) :410-414

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