Fabrication of nanoparticles for biosensing using UV-NIL and lift-off

Tina Mitteramskogler; Michael Haslinger; Astrit Shoshi; Stefan Schrittwieser; Joerg Schotter; Hubert Brueckl; Michael Mühlberger

doi:10.1117/12.2323700

Fabrication of nanoparticles for biosensing using UV-NIL and lift-off

Tina Mitteramskogler, Michael Haslinger, Astrit Shoshi, Stefan Schrittwieser, Joerg Schotter, Hubert Brueckl, Michael Mühlberger

Publikation: Konferenzbeitrag › Papier

Abstract

A novel technique to realize large quantities of stacked multifunctional anisotropic nanoparticles with narrow size distribution is presented. Through the combination of Ultraviolet Nano-Imprint Lithography (UV-NIL), physical vapor deposition and subsequent lift-off processes we fabricate and disperse these particles in solution for the use in biomolecular sensing applications. Compared to chemical nanoparticle synthesis our approach holds several advantages. First, one can control the nanoparticle shape by choosing an appropriate nanopattern for the UV-NIL process. Second, we can choose the composition of the nanoparticles as the materials are deposited layer-wise by sputter deposition. Third, we can fabricate nanoparticles with very small geometrical variations. This is in contrast to chemical synthesis methods where the layer thicknesses and particle size distribution are harder to control.

Originalsprache	Englisch
Seiten	7
DOIs	https://doi.org/10.1117/12.2323700
Publikationsstatus	Veröffentlicht - 19 Sep. 2018
Extern publiziert	Ja
Veranstaltung	34th European Mask and Lithography Conference - Grenoble, France Dauer: 19 Juni 2018 → 20 Juni 2018

Konferenz

Konferenz	34th European Mask and Lithography Conference
Zeitraum	19/06/18 → 20/06/18

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10.1117/12.2323700

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title = "Fabrication of nanoparticles for biosensing using UV-NIL and lift-off",

abstract = "A novel technique to realize large quantities of stacked multifunctional anisotropic nanoparticles with narrow size distribution is presented. Through the combination of Ultraviolet Nano-Imprint Lithography (UV-NIL), physical vapor deposition and subsequent lift-off processes we fabricate and disperse these particles in solution for the use in biomolecular sensing applications. Compared to chemical nanoparticle synthesis our approach holds several advantages. First, one can control the nanoparticle shape by choosing an appropriate nanopattern for the UV-NIL process. Second, we can choose the composition of the nanoparticles as the materials are deposited layer-wise by sputter deposition. Third, we can fabricate nanoparticles with very small geometrical variations. This is in contrast to chemical synthesis methods where the layer thicknesses and particle size distribution are harder to control.",

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AU - Mitteramskogler, Tina

AU - Haslinger, Michael

AU - Shoshi, Astrit

AU - Schrittwieser, Stefan

AU - Schotter, Joerg

AU - Brueckl, Hubert

AU - Mühlberger, Michael

PY - 2018/9/19

Y1 - 2018/9/19

N2 - A novel technique to realize large quantities of stacked multifunctional anisotropic nanoparticles with narrow size distribution is presented. Through the combination of Ultraviolet Nano-Imprint Lithography (UV-NIL), physical vapor deposition and subsequent lift-off processes we fabricate and disperse these particles in solution for the use in biomolecular sensing applications. Compared to chemical nanoparticle synthesis our approach holds several advantages. First, one can control the nanoparticle shape by choosing an appropriate nanopattern for the UV-NIL process. Second, we can choose the composition of the nanoparticles as the materials are deposited layer-wise by sputter deposition. Third, we can fabricate nanoparticles with very small geometrical variations. This is in contrast to chemical synthesis methods where the layer thicknesses and particle size distribution are harder to control.

AB - A novel technique to realize large quantities of stacked multifunctional anisotropic nanoparticles with narrow size distribution is presented. Through the combination of Ultraviolet Nano-Imprint Lithography (UV-NIL), physical vapor deposition and subsequent lift-off processes we fabricate and disperse these particles in solution for the use in biomolecular sensing applications. Compared to chemical nanoparticle synthesis our approach holds several advantages. First, one can control the nanoparticle shape by choosing an appropriate nanopattern for the UV-NIL process. Second, we can choose the composition of the nanoparticles as the materials are deposited layer-wise by sputter deposition. Third, we can fabricate nanoparticles with very small geometrical variations. This is in contrast to chemical synthesis methods where the layer thicknesses and particle size distribution are harder to control.

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DO - 10.1117/12.2323700

M3 - Paper

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T2 - 34th European Mask and Lithography Conference

Y2 - 19 June 2018 through 20 June 2018

ER -

Fabrication of nanoparticles for biosensing using UV-NIL and lift-off

Abstract

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