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Journal of Nanoparticle Research

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01.07.2011 | Research paper

Nano-structuring of PTFE surface by plasma treatment, etching, and sputtering with gold

verfasst von: Alena Reznickova, Zdenka Kolska, Vladimir Hnatowicz, Vaclav Svorcik

Erschienen in: Journal of Nanoparticle Research | Ausgabe 7/2011

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Abstract

Properties of pristine, plasma modified, and etched (by water and methanol) polytetrafluoroethylene (PTFE) were studied. Gold nanolayers sputtered on this modified PTFE have been also investigated. Contact angle, measured by goniometry, was studied as a function of plasma exposure and post-exposure aging times. Degradation of polymer chains was examined by etching of plasma modified PTFE in water or methanol. The amount of ablated and etched layer was measured by gravimetry. In the next step the pristine, plasma modified, and etched PTFE was sputtered with gold. Changes in surface morphology were observed using atomic force microscopy. Chemical structure of modified polymers was characterized by X-ray photoelectron spectroscopy (XPS). Surface chemistry of the samples was investigated by electrokinetic analysis. Sheet resistance of the gold layers was measured by two-point technique. The contact angle of the plasma modified PTFE decreases with increasing exposure time. The PTFE amount, ablated by the plasma treatment, increases with the plasma exposure time. XPS measurements proved that during the plasma treatment the PTFE macromolecular chains are degraded and oxidized and new –C–O–C–, –C=O, and –O–C=O groups are created in modified surface layer. Surface of the plasma modified PTFE is weakly soluble in methanol and intensively soluble in water. Zeta potential and XPS shown dramatic changes in PTFE surface chemistry after the plasma exposure, water etching, and gold deposition. When continuous gold layer is formed a rapid decrease of the sheet resistance of the gold layer is observed.

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Barr TL (1994) Modern ESCA. CRC Press, Boca Raton

Chopra K (1969) Thin film phenomena. Wiley, New York

Gerenser LJ (1993) XPS Studies of in situ plasam-modified polymer. J Adhes Sci Technol 7:1019–1040CrossRef

Goddard JM, Hotchkiss JH (2007) Polymer surface modification for the attachment of bioactive compunds. Prog Polym Sci 32:698–725CrossRef

Hiemenz P, Rajagopalan R (1997) Principles of colloid and surface chemistry. Marcel Dekker, New York

Kaune G, Ruderer MA, Metwalli E, Wang W, Couet S, Schlage K, Röhlsberger R, Roth SV, Müller-Buschbaum P (2009) In situ GISAXS study of gold film growth on conducting polymer films. ACS Appl Mater Interfaces 1:353–362CrossRef

Kotál V, Švorčík V, Slepička P, Sajdl P, Bláhová O, Hnatowicz V (2007) Gold coating of poly(ethylene terephthalate) modified by argon plasma. Plasma Process Polym 4:69–76CrossRef

Liu CZ, Wu JQ, Ren LQ, Tong J, Li JQ, Cui N et al (2004) Comparative study on the effect of RF and DBD plasma treatment on PTFE surface modification. Mater Chem Phys 85:340–346CrossRef

Nakao S, Ando T, Shikida M, Satol K (2006) Mechanical properties of a micron-sized SCS film in a high-temperature environment. J Micromech Microeng 16:715–720CrossRef

Nazabal V, Fargin E, Labrugere C, Le Flem G (2000) Second harmonic generation optimization in thermally poled borophosphate glasses and characterization by XANES and XPS. J Non Cryst Solids 270:223–233CrossRef

Noh JH, Baik HK, Noh I, Park J, Lee I (2007) Surface modification of PTFE using atmospheric pressure plasma jet for medical application. Surf Coat Technol 201:5097–5101CrossRef

Okubo M, Tahara M, Saeki N, Yamamoto T (2008) Surface modification of fluorocarbon polymer films for improved adhesion using atmospheric-pressure nonthermal plasma graft-polymerization. Thin Solid Films 516:6592–6597CrossRef

Řezníčková A, Kolská Z, Hnatowicz V, Stopka P, Švorčík V (2011) Comparison of glow argon plasma-induced surface changes of thermoplastic polymers. Nucl Instrum Methods B 269:83–88

Siegel J, Řezníčková A, Chaloupka A, Slepička P, Švorčík V (2008) Ablation and water etching of plasma treated polymers. Radiat Eff Defect Solid 163:779–788

Slepička P, Švorčík V, Šlouf M, Rybka V, Špirková M (2008) Characterization of metal nanolayers sputtered on poly(ethyleneterephtalate). Optoel Adv Mater Commun 2:153–160

Slepička P, Kolská Z, Náhlík J, Hnatowicz V, Švorčík V (2009) Properties of Au nanolayers on polyethylene and polytetrafluoroethlene. Surf Interface Anal 41:741–745CrossRef

Stutzmann N, Tervort TA, Bastiaansen K, Smith P (2000) Patterning of polymer-supported metal films by microcutting. Nature 407:613–616CrossRef

Švorčík V, Zehentner J, Rybka V, Slepička P, Hnatowicz V (2002) Characterization of thin gold layers on PET: transition from discontinuous to continuous, homogenous layer. Appl Phys A 75:541–544CrossRef

Švorčík V, Kotál V, Slepička P, Bláhová O, Špírková M, Sajdl P et al (2006a) Modification of surface properties of PE by Ar plasma discharge. Nucl Instrum Methods B 244:365–372CrossRef

Švorčík V, Kotál V, Slepička P, Bláhová O, Šutta P, Hnatowicz V (2006b) Gold coating of PE modified by argon plasma discharge. Polym Eng Sci 46:1326–1332CrossRef

Švorčík V, Kolářová K, Slepička P, Macková A, Novotná M, Hnatowicz V (2006c) Modification of surface properties of high and low density PE by Ar plasma discharge. Polym Degrad Stab 91:1219–1225CrossRef

Švorčík V, Kotál V, Siegel J, Sajdl P, Macková A, Hnatowicz V (2007) Ablation and water etching of poly(ethylene) modified by argon plasma. Polym Degrad Stab 97:1645–1649

Švorčík V, Chaloupka A, Záruba K, Král V, Bláhová O, Macková A (2009a) Deposition of gold nano-particles and nano-layers on polyethylene modified by plasma discharge and chemical treatment. Nucl Instrum Methods B 267:2484–2488CrossRef

Švorčík V, Kasálková N, Slepička P, Záruba K, Bačáková L, Pařízek M et al (2009b) Cytocompatibility of Ar plasma-treated and Au nanoparticle-grafted PE. Nucl Instrum Methods B 267:1904–1910CrossRef

Švorčík V, Kolská Z, Luxbacher T, Mistrík J (2010a) Properties of Au nanolayer sputtered on polyethyleneterphtalate. Mater Lett 64:1160–1162CrossRef

Švorčík V, Řezníčková A, Kolská Z, Slepička P (2010b) Variable surface properties of PTFE foils. e-Polymers 133:1–6

Tahara M, Cuong NK, Nakashima Y (2003) Improvement in adhesion of polyethylene by glow-discharge plasma. Surf Coat Technol 174:826–830CrossRef

Tendero C, Tixier C, Tristant P, Desmaison J, Leprince P (2006) Atmospheric pressure plasmas: a review. Spectrochim Acta B 61:2–30CrossRef

Wang S, Li J, Suo J, Luo T (2010) Surface modification of porous poly(tetrafluoroethylene) by a simple chemical oxidation treatment. Appl Surf Sci 256:2293–2298CrossRef

Titel: Nano-structuring of PTFE surface by plasma treatment, etching, and sputtering with gold
verfasst von: Alena Reznickova
Zdenka Kolska
Vladimir Hnatowicz
Vaclav Svorcik
Publikationsdatum: 01.07.2011
Verlag: Springer Netherlands
Erschienen in: Journal of Nanoparticle Research / Ausgabe 7/2011
Print ISSN: 1388-0764
Elektronische ISSN: 1572-896X
DOI: https://doi.org/10.1007/s11051-010-0183-0

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