From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study

Rahe, Philipp; Lindner, Robert; Kittelmann, Markus; Nimmrich, Markus; Kühnle, Angelika

From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study

Rahe P, Lindner R, Kittelmann M, Nimmrich M, Kühnle A (2012)
Physical Chemistry Chemical Physics 14: 6544.

Zeitschriftenaufsatz | Veröffentlicht | Englisch

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PhysChemChemPhys_14_2012_Rahe.pdf 4.85 MB

DOI

https://doi.org/10.1039/c2cp40172j

URN

urn:nbn:de:0070-pub-29138160

Autor*in

Rahe, Philipp; Lindner, Robert; Kittelmann, Markus; Nimmrich, Markus; Kühnle, Angelika^UniBi

Einrichtung

Fakultät für Chemie > Physikalische Chemie I

Abstract / Bemerkung

We report the formation of extended molecular layers of C-60 molecules on a dielectric surface at room temperature. In sharp contrast to previous C-60 adsorption studies on prototypical ionic crystal surfaces, a wetting layer is obtained when choosing the calcite (CaCO3)(10 (1) over bar4) surface as a substrate. Non-contact atomic force microscopy data reveal an excellent match of the hexagonal lattice of the molecular layer with the unit cell dimension of CaCO3(10 (1) over bar4) in the [01 (1) over bar0] direction, while a lattice mismatch along the [(4) over bar(2) over bar 61] direction results in a large-scale moire modulation. Overall, a (2 x 15) wetting layer is obtained. The distinct difference observed microscopically upon C-60 adsorption on CaCO3(10 (1) over bar4) compared to other dielectric surfaces is explained by a macroscopic picture based on surface energies. Our example demonstrates that this simple surface-energy based approach can provide a valuable estimate for choosing molecule-insulator systems suitable for molecular self-assembly at room temperature.

Erscheinungsjahr

2012

Zeitschriftentitel

Physical Chemistry Chemical Physics

Band

Seite(n)

6544

Urheberrecht / Lizenzen

Creative Commons Namensnennung 4.0 International Public License (CC-BY 4.0)

ISSN

1463-9076

Page URI

https://pub.uni-bielefeld.de/record/2913816

Zitieren

Rahe P, Lindner R, Kittelmann M, Nimmrich M, Kühnle A. From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study. Physical Chemistry Chemical Physics. 2012;14:6544.

Rahe, P., Lindner, R., Kittelmann, M., Nimmrich, M., & Kühnle, A. (2012). From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study. Physical Chemistry Chemical Physics, 14, 6544. https://doi.org/10.1039/c2cp40172j

Rahe, Philipp, Lindner, Robert, Kittelmann, Markus, Nimmrich, Markus, and Kühnle, Angelika. 2012. “From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study”. Physical Chemistry Chemical Physics 14: 6544.

Rahe, P., Lindner, R., Kittelmann, M., Nimmrich, M., and Kühnle, A. (2012). From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study. Physical Chemistry Chemical Physics 14, 6544.

Rahe, P., et al., 2012. From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study. Physical Chemistry Chemical Physics, 14, p 6544.

P. Rahe, et al., “From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study”, Physical Chemistry Chemical Physics, vol. 14, 2012, pp. 6544.

Rahe, P., Lindner, R., Kittelmann, M., Nimmrich, M., Kühnle, A.: From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study. Physical Chemistry Chemical Physics. 14, 6544 (2012).

Rahe, Philipp, Lindner, Robert, Kittelmann, Markus, Nimmrich, Markus, and Kühnle, Angelika. “From dewetting to wetting molecular layers:C60 on CaCO3(1014) as a case study”. Physical Chemistry Chemical Physics 14 (2012): 6544.

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2019-09-06T09:18:51Z

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