Joakim Järnström scite author profile

Thin and narrow conductive patterns of metal (silver) and organic polymer (polyaniline) were printed on various coated paper samples. A detailed characterization of the physical properties (i.e., short length scale roughness, surface energy, and air permeability) of the paper samples was conducted. These properties were correlated with print quality (print resolution and edge waviness) and electrical performance (resistance) of the printed wires. A plastic film was used as a reference substrate. The print resolution and the magnitude of the edge waviness were affected by the complex interplay of different physical properties of both the substrate and the ink. On the other hand, the resistance of the printed wires was found to correlate linearly with the short length scale roughness of the print substrate. The electrical performance of the paper substrates showing the highest conductivity for the printed patterns was comparable to that of the plastic film. The paper substrate on which the printed wires showed the best electrical performance was used as a substrate for fabrication of an organic transistor with low operating voltage.

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H₂S modified atomic layer deposition process for photocatalytic TiO₂thin films

Pore

Ritala

Leskelä

et al. 2007

J. Mater. Chem.

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Roughness of pigment coatings and its influence on gloss

Järnström¹,

Ihalainen²,

Backfolk³

et al. 2008

Applied Surface Science

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Effects of atmospheric plasma activation on surface properties of pigment-coated and surface-sized papers

Pykönen

Sundqvist

Järnström

et al. 2008

Applied Surface Science

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Effect of latex on surface structure and wetting of pigment coatings

Järnström¹,

Väisänen²,

Lehto³

et al. 2010

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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