Detail publikačního výsledku

Parylene Micropillars Coated with Thermally Grown SiO2

LIU, X.; FECKO, P.; FOHLEROVÁ, Z.; PEKÁREK, J.; KARÁSEK, T.; NEUŽIL, P.

Originální název

Parylene Micropillars Coated with Thermally Grown SiO2

Anglický název

Parylene Micropillars Coated with Thermally Grown SiO2

Druh

Článek WoS

Originální abstrakt

The modification of surface properties frequently requires the binding of suitable compounds to the original surface. Silanes or thiols can be directly covalently bonded to either Si-based materials or Au, thus ruling out polymers. Here, we show the utilization of a layer of SiO2 with a thickness of a few nanometers that serves as a cross-linker between polymers and silanes providing covalent bonding to the surface. We deposited a polymer onto a thermally oxidized microstructured Si surface followed by subsequent Si removal. We demonstrated a Si-based nanotechnology fabrication method that can be generally used to modify the surface properties of practically any polymer via SiO2 cross-linking. This can produce any topology, including microstructures, nanostructures, or composite microstructure/nanostructures terminating in different shapes, since all the steps involving polymer deposition are conducted at room temperature after the Si surface has been thermally oxidized. This technique opens a broad field of new applications for polymers in microstructures and nanostructures that have stable water surface contact angle values with the contact angle set by demand for gecko-mimicking structures or lotus leaf inspired surfaces.

Anglický abstrakt

The modification of surface properties frequently requires the binding of suitable compounds to the original surface. Silanes or thiols can be directly covalently bonded to either Si-based materials or Au, thus ruling out polymers. Here, we show the utilization of a layer of SiO2 with a thickness of a few nanometers that serves as a cross-linker between polymers and silanes providing covalent bonding to the surface. We deposited a polymer onto a thermally oxidized microstructured Si surface followed by subsequent Si removal. We demonstrated a Si-based nanotechnology fabrication method that can be generally used to modify the surface properties of practically any polymer via SiO2 cross-linking. This can produce any topology, including microstructures, nanostructures, or composite microstructure/nanostructures terminating in different shapes, since all the steps involving polymer deposition are conducted at room temperature after the Si surface has been thermally oxidized. This technique opens a broad field of new applications for polymers in microstructures and nanostructures that have stable water surface contact angle values with the contact angle set by demand for gecko-mimicking structures or lotus leaf inspired surfaces.

Klíčová slova

micropillars, SiO2, parylene

Klíčová slova v angličtině

micropillars, SiO2, parylene

Autoři

LIU, X.; FECKO, P.; FOHLEROVÁ, Z.; PEKÁREK, J.; KARÁSEK, T.; NEUŽIL, P.

Rok RIV

2021

Vydáno

09.11.2020

ISSN

2166-2746

Periodikum

Journal of Vacuum Science & Technology B

Svazek

38

Číslo

1

Stát

Spojené státy americké

Strany od

38

Strany do

43

Strany počet

6

URL

https://avs.scitation.org/doi/10.1116/6.0000558

BibTex

@article{BUT165596,
  author="LIU, X. and FECKO, P. and FOHLEROVÁ, Z. and PEKÁREK, J. and KARÁSEK, T. and NEUŽIL, P.",
  title="Parylene Micropillars Coated with Thermally Grown SiO2",
  journal="Journal of Vacuum Science & Technology B",
  year="2020",
  volume="38",
  number="1",
  pages="38--43",
  doi="10.1116/6.0000558",
  issn="2166-2746",
  url="https://avs.scitation.org/doi/10.1116/6.0000558"
}

Dokumenty

JVB20-AR-EIPBN2020-00361R1_Merged_PDF