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Stamp fabrication by step and stamp nanoimprinting

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dc.contributor Aalto-yliopisto fi
dc.contributor Aalto University en
dc.contributor.advisor Ahopelto, Jouni, Prof.
dc.contributor.author Haatainen, Tomi
dc.date.accessioned 2012-08-29T10:07:48Z
dc.date.available 2012-08-29T10:07:48Z
dc.date.issued 2011
dc.identifier.isbn 978-951-38-7727-9 (PDF)
dc.identifier.isbn 978-951-38-7726-2 (printed) #8195;
dc.identifier.issn 1455-0849
dc.identifier.uri https://aaltodoc.aalto.fi/handle/123456789/4938
dc.description.abstract The nanoimprinting is a potential method for submicron scale patterning for various applications, for example, electric, photonic and optical devices. The patterns are created by mechanical deformation of imprint resist using a patterned imprinting mold called also a stamp. The bottle-neck for imprint lithography is availability of the stamps with nanometer-scale features, which are typically fabricated by electron beam lithography. Therefore, patterning of a large stamp is time consuming and expensive. Nanoimprint lithography can offer a low cost and a high through-put method to replicate these imprinting molds. In this work, stamp replication process was developed and demonstrated for three different types of imprint molds. Replication relies on sequential patterning method called step and stamp nanoimprint lithography (SSIL). In this method a small master mold is used to pattern large areas sequentially. The fabricated stamps are hard stamps for thermal imprinting, bendable metal stamps for roll embossing and transparent stamps for UV-imprinting. Silicon is a material often used for fabrication of hard stamps for thermal imprinting. Fabrication process of silicon stamps was demonstrated using both the imprinted resist and lift-off process for pattern transfer into silicon. Bendable metal stamp for roll-to-roll application was fabricated using sequential imprinting to fabricate a polymer mold. The polymer mold was used for fabrication of a nickel copy in subsequent electroplating process. Thus fabricated metal stamp was used in a roll-to-roll imprinting process to transfer the patterns onto a CA film successfully. Polymer stamp for UV-imprinting was fabricated by patterning fluorinated polymer templates using sequential imprinting and a silicon stamp. The imprinted polymer stamp was used succesfully for UV-NIL. In the stamp fabrication process the features of the silicon stamp were replicated with good fidelity, retaining the original dimensions in all of three stamp types. The results shows, that the sequential imprinting is as a potential stamp replication method for various applications. en
dc.format.extent Verkkokirja (4966 KB, 71 s.)
dc.format.mimetype application/pdf
dc.language.iso en en
dc.publisher Aalto University en
dc.relation.ispartofseries VTT publications, 758 en
dc.relation.haspart [Publication 1]: Haatainen, T., Ahopelto, J., Gruetzner, G., Fink, M. and Pfeiffer, K. Step & stamp imprint lithography using commercial flip chip bonder. Proc. SPIE. 3997 (2000), pp. 874-880. en
dc.relation.haspart [Publication 2]: Haatainen, T. and Ahopelto, J. Pattern Transfer using Step & Stamp Imprint Lithography. Phys. Scri. 67(4) (2003), pp. 357-360. en
dc.relation.haspart [Publication 3]: Haatainen, T., Majander, P., Riekkinen, T. and Ahopelto, J. Nickel stamp fabrication using step & stamp imprint lithography. Microelectron. Eng. 83 (2006), pp. 948-950. en
dc.relation.haspart [Publication 4]: Mäkelä, T., Haatainen, T., Majander, P., Ahopelto, J. and Lambertini, V. Continuous Double-Sided Roll-to-Roll Imprinting of Polymer Film. Jpn. J. Appl. Phys. 47(6) (2008), pp. 5142-5144. en
dc.relation.haspart [Publication 5]: Haatainen, T., Majander, P., Mäkelä, T., Ahopelto, J. and Kawaguchi, Y. Imprinted 50 nm Features Fabricated by Step and Stamp UV Imprinting. Jpn. J. Appl. Phys. 47(6) (2008), pp. 5164-5166. en
dc.relation.haspart [Publication 6]: Haatainen, T., Mäkelä, T., Ahopelto, J., and Kawaguchi, Y. Imprinted polymer stamps for UV-NIL. Microelectron. Eng. 86(11) (2009), pp. 2293-2296. en
dc.relation.haspart [Publication 7]: Courgon, G., Chaix, N., Schift, H., Tormen, M., Landis, S., Sotomayor Torres, C., Kristensen, A., Pedersen, R. H., Christiansen, M. B., Fernandez-Cuesta, I., Mendels, D., Montelius, L. and Haatainen, T. Benchmarking of 50 nm features in thermal nanoimprint. J. Vac. Sci. Technol. B25(6) (2007), pp. 2373-2378. en
dc.relation.haspart [Publication 8]: Alternative Lithography: Unleashing the potentials of Nanotechnology, edited by C. M. Sotomayor-Torres, University of Wuppertal: Ahopelto, J. and Haatainen, T.: In chapter 6 "Step and Stamp Imprint Lithography", Kluwer Academic/Plenum Publishers, New York 2003. Pp. 103-115. en
dc.subject.other Publication
dc.subject.other Technology
dc.title Stamp fabrication by step and stamp nanoimprinting en
dc.type G5 Artikkeliväitöskirja fi
dc.contributor.school Sähkötekniikan korkeakoulu fi
dc.contributor.department Department of Micro and Nanosciences en
dc.contributor.department Mikro- ja nanotekniikan laitos fi
dc.subject.keyword nanoprinting en
dc.subject.keyword hot embossing en
dc.subject.keyword stamp replication en
dc.identifier.urn URN:ISBN:978-951-38-7727-9
dc.type.dcmitype text en
dc.type.ontasot Väitöskirja (artikkeli) fi
dc.type.ontasot Doctoral dissertation (article-based) en
dc.contributor.supervisor Kuivalainen, Pekka, Prof.
local.aalto.digifolder Aalto_66922
local.aalto.digiauth ask

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