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Scanning tunneling microscopy study of molecular order at liquid-solid interfaces (1994)

Magonov, S. N. ; Wawkuschewski, A. ; Cantow, H. -J. ; [et al.]

Springer

Applied physics 59 (1994), S. 119-133

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ISSN: 1432-0630

Keywords: 68.45 ; 68.55 ; 73.60

Source: Springer Online Journal Archives 1860-2000

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics , Physics

Notes: Abstract Adsorbates of normal alkane C36H74, cycloalkanes (CH2)48 and (CH2)72, decanol C10H21OH, 4-hexyl-4′-CyanoBiphenyl (6CB) and 4-octyl-4t′-CyanoBiphenyl (8CB) on graphite and β-Nb3I8 were studied by Scanning Tunneling Microscopy (STM), and the molecular arrangements at the liquid-solid interface were examined. Large-scale STM images show that the adsorbates possess complex multilayered structures, and that molecular ordering at the liquid-solid interfaces occurs primarily in the immediate vicinity of the substrate. Molecular-scale STM images are primarily determined by the electronic contributions of the most protruded atoms of the topmost overlayer. The underlying overlayers and the substrate affect the images indirectly by perturbing the topography of the topmost overlayer. The STM images of the adsorbates on graphite show that the atomically flat surface of graphite leads organic molecules to form lamella-like structures, while on the grooved surface of β-Nb3I8, long chain-like molecules are trapped in the grooves. We were unable to image the cycloalkanes on β-Nb3I8, which suggests that the cycloalkanes cannot assemble on the grooved surface due to a mismatch between the molecular shape and surface topography. The layers of 6CB and 8CB adsorbed on β-Nb3I8 exhibit two types of domains, which may be related to how the grooves of the β-Nb3I8 surface are occupied by the organic molecules. The STM images of decanol adsorbed on β-Nb3I8 show two domains of different brightness. The relative brightness of these domains switches reversibly as the gap resistance is changed in the region around −60 MΩ.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00332204

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Scanning force microscopy of high modulus polyethylene fibers (1995)

Wawkuschewski, A. ; Cantow, H. -J. ; Magonov, S. N. ; [et al.]

Weinheim : Wiley-Blackwell

Acta Polymerica 46 (1995), S. 168-177

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ISSN: 0323-7648

Keywords: Chemistry ; Polymer and Materials Science

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology , Physics

Notes: Surfaces of commercial ultrastrong polymer fibers Spectra® 900 and Spectra® 1000, which are produced by gel-spinning of ultrahigh molecular weight polyethylene (UHWM PE), were examined with scanning force microscopy (SFM). Measurements were conducted in water in order to minimize surface damage caused by the tip-sample interactions. Different types of imperfections (arbitrarily oriented fibrils, ends of fibrils and discontinuities in surface layers) were found on the fiber surface. These features interfere with the dominating fibrillar structure aligned along the fiber direction. Within the fibrillar structure were found domains of ribbon-like features with a width of 30--110 nm. These ribbons are oriented perpendicular to the fiber direction and were assigned to lamellar platelets overgrown on oriented nanofibrils. SFM images in the nanoscale (1--100 nm) showed that nanofibrils 5--7 nm wide are the elementary construction elements of polymer fibers. They are combined into larger fibrils of 40--50 nm width. Needle-type crystallites 10--30 nm wide were also found on the fiber surface. An extended chain molecular order was detected on surfaces of nanofibrils, needle crystallites, and within the central part of lamellar ribbons. Local regions with long period features having a repeat distance of 15--25 nm were found on the fiber surface. Etching of the fiber surface by elemental fluorination damaged the surface fibrillar structure, and produced deep pores tens of nanometer in diameter in the surface layer.

Additional Material: 8 Ill.