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Scalable nanostructuring on polymer by a SiC stamp: optical and wetting effects
Aikaterini Argyraki, Weifang Lu, Paul Michael Petersen, Haiyan Ou
Department of Photonics Engineering, Technical University of Denmark
Outline
2Technical University of Denmark Aikaterini Argyraki
Motivation
- Wafer-Scale nanostructuring of SiC stamp- Replication of nanostructures on a polymer
surface
-Optical effects -Wetting properties
Conclusions
Fab
ricati
on
Ch
ara
cte
rizati
on
3Technical University of Denmark Aikaterini Argyraki
Motivation
Push performance of devices towards their optimum limits by controlable fabrication of interfaces at the nanoscopic level.
Polymer materials gain interest both as semiconductors and conductors due to their low cost.
Prerequisites
Fabrication of nanostructures that result in macroscale effects with reproducibility !
and….nanopattern definition must be:• Rapid• Low-cost• Applicable on wafer scale-high throughput
4Technical University of Denmark Aikaterini Argyraki
SiC nanostructuring: summary table
5
Type of structures
Method Average Reflectance (%)
Luminecence enhancement (from 10 to 80 degrees)
Periodic E-beam 1,01 104%
Semi-periodic Self-assembly 1,62 67%
Periodic Semi-periodic
Technical University of Denmark Aikaterini Argyraki
*Reference:
Y. Ou, et al., Optics Express 20, 7, 2012.
Y. Ou, et al., Opt. Lett. 37, 18, 2012.
A cost effective method for SiC aperiodic nanostructuring
Technical University of Denmark Aikaterini Argyraki 6
Combinatory masking
200nm
Technical University of Denmark Aikaterini Argyraki 7
04-06-2013
Ramping:
RIE conditions+
Al thickness
*Reference:
A. Argyraki et al., Optical Materials Express 8(3) 2013.
Fabrication of different nanotopographies
Color texture changes due to nanostructuring
9
Optical properties: Reflection, Transmission
Technical University of Denmark Aikaterini Argyraki 10
Average 25%
Average 5%
Average 0,5%
Average 37%
Average 33%
Average 13%
Scalability
Technical University of Denmark Aikaterini Argyraki 11
Summary table
12
Type of structures
Method Average Reflectance (%)
Luminecence enhancement (from 10 to 80 degrees)
Periodic E-beam 1,01 104%
Semi-periodic Self-assembly* 1,62 67%
Stochastic Combinatory masking
0,50 165%
Periodic Semi-periodic
Technical University of Denmark Aikaterini Argyraki
Stochastic
*Reference:
Ou, H., Advances in wide bandgap SiC for optoelectronics, The European Physical Journal B
Replication of nanostructures on polymer
Technical University of Denmark Aikaterini Argyraki 13
Process flow
Ni shim: generation
Technical University of Denmark Aikaterini Argyraki 14
Nanostructured polymer surface
Technical University of Denmark Aikaterini Argyraki 15
Color textures after nanostructuring on polymer
A thin Al layer (~40nm)
16
Optical and wetting properties after nanostructuring on polymer
68 degrees 123 degrees
Polymer-bare Polymer-nano Al coated-bare Al coated-nano
75 degrees 132 degrees
Average 11%
Average 5%
Average 3%
Average 88%
Average 85%
Average 33%
Conclusions
• Demonstrated 2 inch wafer nanostructuring on polymer by a SiC stamp
• Color texture and transmitance of SiC surface was controled by nanotopography applied
• Color texture and reflectance of polymer surface was significantly altered by nanostructuring and additional deposition of a thin Al layer
• Wetting properties of surfaces shifted after nanostructuring from hydrophilic to hydrophobic
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Acknowledgment
Technical University of Denmark Aikaterini Argyraki 19
Weifang Lu Yiyu Ou Paul Michael Petersen Haiyan Ou
Thank you for your attention
Contact info: [email protected]
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