Publication: Large-scale nano piezo force position arrays as ultrahigh-resolution micro- and nanoparticle tracker
Issued Date
2013-01-14
Resource Type
ISSN
16163028
1616301X
1616301X
Other identifier(s)
2-s2.0-84872057942
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Mahidol University
Rights Holder(s)
SCOPUS
Bibliographic Citation
Advanced Functional Materials. Vol.23, No.2 (2013), 191-197
Suggested Citation
Kittitat Subannajui, Andreas Menzel, Firat Güder, Yang Yang, Katrin Schumann, Xiaoli Lu, Margit Zacharias Large-scale nano piezo force position arrays as ultrahigh-resolution micro- and nanoparticle tracker. Advanced Functional Materials. Vol.23, No.2 (2013), 191-197. doi:10.1002/adfm.201201201 Retrieved from: https://repository.li.mahidol.ac.th/handle/123456789/31558
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Title
Large-scale nano piezo force position arrays as ultrahigh-resolution micro- and nanoparticle tracker
Abstract
Defining the position of an object on a planar substrate by force sensors is a common technology nowadays. Many products are commercialized worldwide, which make use of force sensors, especially, for instance, touchpads. Here advanced lithography processes together with piezoelectric materials are demonstrated to fabricate an extremely high resolution force sensor. The approach combines a large array of nanoscale piezoelectric lines fabricated on Si wafer by phase-shift lithography and atomic-layer-deposition-based spacer lithography techniques. These key lithography methods are utilized to fabricate ultralong (cm range) nanolines on the wafer scale. ZnO and P(VDF-TrFE) are selected here as materials for piezoelectric signal generators. The detection mechanisms are explained and simulations combined with experimental data are demonstrated to prove the concept. The signal generated when an object approaches one single line is in the nanoampere range. The result enables a new and simple path for a device fabrication, which defines the position with micro- and nanometer resolution and can be used, for example, as micro- and nanoparticle trackers. Advanced lithographic processes combined with piezoelectric materials have the potential to fabricate extremely high resolution force position arrays on a large scale. Nanometer-scale piezoelectric lines fabricated on Si wafers by phase-shift lithography and atomic-layer-deposition-based spacer lithography techniques are utilized to enable a new and simple path for devices that define the position with micro- and nanometer resolution. Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.