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Statements

Subject Item
n2:RIV%2F60461373%3A22310%2F13%3A43896405%21RIV14-GA0-22310___
rdf:type
n3:Vysledek skos:Concept
dcterms:description
In particular, last decade our group dedicated to study preparation of nanostructures and nanostructuring of solid surfaces using especially plasma treatment, laser irradiation and thermal modification. Up to this day many efforts have been spent to produce smart materials with extraordinary properties usable in board range of technological applications. In last two decades it has been demonstrated that production of materials with completely new properties does not crucially depend only on its chemical composition but also significantly on the dimensions of building blocks of conventionally known materials. Primarily, our group dealt with structures which could find its application in tissue engineering (cell adhesion and proliferation improvement), electronics (adhesion improvement between polymer or glass substrate and metal coatings) and optoelectronics (optical lattice). In this chapter we are going to focuse on preparation and characterization of nanostructures prepared on polymer or glass surfaces. These materials were modified by plasma and laser treatment and subsequently subjected to various analytical methods to reveal e.g.: chemical structure (FTIR, UV-Vis, XPS, AAS, RBS and Raman spectroscopy), electrical properties (sheet resistance, Van der Pauw method), optical properties (ellipsometry), ablation of layer (gravimetry), surface properties (AFM, FIB-SEM, goniometry, electrokinetic analysis), crystallinity (XRD). In particular, last decade our group dedicated to study preparation of nanostructures and nanostructuring of solid surfaces using especially plasma treatment, laser irradiation and thermal modification. Up to this day many efforts have been spent to produce smart materials with extraordinary properties usable in board range of technological applications. In last two decades it has been demonstrated that production of materials with completely new properties does not crucially depend only on its chemical composition but also significantly on the dimensions of building blocks of conventionally known materials. Primarily, our group dealt with structures which could find its application in tissue engineering (cell adhesion and proliferation improvement), electronics (adhesion improvement between polymer or glass substrate and metal coatings) and optoelectronics (optical lattice). In this chapter we are going to focuse on preparation and characterization of nanostructures prepared on polymer or glass surfaces. These materials were modified by plasma and laser treatment and subsequently subjected to various analytical methods to reveal e.g.: chemical structure (FTIR, UV-Vis, XPS, AAS, RBS and Raman spectroscopy), electrical properties (sheet resistance, Van der Pauw method), optical properties (ellipsometry), ablation of layer (gravimetry), surface properties (AFM, FIB-SEM, goniometry, electrokinetic analysis), crystallinity (XRD).
dcterms:title
Nanostructuring of Solid Surfaces Nanostructuring of Solid Surfaces
skos:prefLabel
Nanostructuring of Solid Surfaces Nanostructuring of Solid Surfaces
skos:notation
RIV/60461373:22310/13:43896405!RIV14-GA0-22310___
n3:predkladatel
n6:orjk%3A22310
n4:aktivita
n20:P
n4:aktivity
P(GA106/09/0125), P(GAP108/10/1106), P(GAP108/12/1168), P(GPP108/11/P337), P(GPP108/11/P840)
n4:dodaniDat
n15:2014
n4:domaciTvurceVysledku
n9:9735208 n9:8378223 n9:5784484 n9:4827465 n9:8407029 n9:2029057 n9:1508733 n9:7940904
n4:druhVysledku
n16:C
n4:duvernostUdaju
n7:S
n4:entitaPredkladatele
n12:predkladatel
n4:idSjednocenehoVysledku
90624
n4:idVysledku
RIV/60461373:22310/13:43896405
n4:jazykVysledku
n17:eng
n4:klicovaSlova
Surfaces; Solid; Nanostructuring
n4:klicoveSlovo
n13:Nanostructuring n13:Surfaces n13:Solid
n4:kontrolniKodProRIV
[FF56FD97C725]
n4:mistoVydani
Hauppauge, New York
n4:nazevEdiceCisloSvazku
Neuveden
n4:nazevZdroje
Nanostructures: Properties, Production Methods and Applications
n4:obor
n5:JJ
n4:pocetDomacichTvurcuVysledku
8
n4:pocetStranKnihy
367
n4:pocetTvurcuVysledku
9
n4:projekt
n10:GA106%2F09%2F0125 n10:GAP108%2F10%2F1106 n10:GAP108%2F12%2F1168 n10:GPP108%2F11%2FP337 n10:GPP108%2F11%2FP840
n4:rokUplatneniVysledku
n15:2013
n4:tvurceVysledku
Slepička, Petr Kvítek, Ondřej Řezníčková, Alena Kolská, Zdeňka Slepičková Kasálková, Nikola Siegel, Jakub Lyutakov, Oleksiy Švorčík, Václav Hubáček, Tomáš
s:numberOfPages
108
n21:hasPublisher
Nova Science Publishers
n19:isbn
978-1-62618-081-9
n14:organizacniJednotka
22310