Proceedings Paper
Research on the growth of dye film in vacuum in situ| Format | Member Price | Non-Member Price |
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Paper Abstract
Organic film deposition in vacuum is fast developing scientific and industrial domain. We developed installation for
deposition of organic films equipped with optical spectrometer for measurements in situ. We are developing new dyes
aimed for application in waveguide sensor, nonlinear optics and studying film organisation during deposition.
Fluorinated azo-dyes and azomethine dyes were synthesized at University of Applied Sciences Wildau and at the
Institute of Organic Chemistry, Kyiv. Compounds were evaporated at a pressure of 10-3 Pa using resistive heated
crucible. Glass and glass covered with polytetrafluoroethylene (PTFE) film are used as substrates. The films were
studied with Polytec and StellarNet spectrometers and an atomic force microscope. Optical spectra of the dye films
revealed, that some compounds were decomposed during evaporation. Several kinds of dyes were evaporated and
deposited without decomposition. Some deposited films formed H-aggregates and other types of aggregates. AFM
images of dye films showed that their morphology depends on the chemical structure of the compounds and on the nature
of the substrate on which the film was grown.
Paper Details
Date Published: 25 April 2008
PDF: 6 pages
Proc. SPIE 6999, Organic Optoelectronics and Photonics III, 69991Z (25 April 2008);
Published in SPIE Proceedings Vol. 6999:
Organic Optoelectronics and Photonics III
Paul L. Heremans; Michele Muccini; Eric A. Meulenkamp, Editor(s)
PDF: 6 pages
Proc. SPIE 6999, Organic Optoelectronics and Photonics III, 69991Z (25 April 2008);
Show Author Affiliations
K. Grytsenko, Institute of Semiconductor Physics (Ukraine)
T. Doroshenko, Institute of Semiconductor Physics (Ukraine)
Yu. Kolomzarov, Institute of Semiconductor Physics (Ukraine)
V. Prokopets, Institute of Semiconductor Physics (Ukraine)
O. Fedoriak, Institute of Semiconductor Physics (Ukraine)
R. Zelinski, Institute of Semiconductor Physics (Ukraine)
O. Lytvyn, Institute of Semiconductor Physics (Ukraine)
D. Prescher, Univ. of Applied Sciences (Germany)
T. Doroshenko, Institute of Semiconductor Physics (Ukraine)
Yu. Kolomzarov, Institute of Semiconductor Physics (Ukraine)
V. Prokopets, Institute of Semiconductor Physics (Ukraine)
O. Fedoriak, Institute of Semiconductor Physics (Ukraine)
R. Zelinski, Institute of Semiconductor Physics (Ukraine)
O. Lytvyn, Institute of Semiconductor Physics (Ukraine)
D. Prescher, Univ. of Applied Sciences (Germany)
B. Grimm, Univ. of Applied Sciences (Germany)
V. Ksianzou, Univ. of Applied Sciences (Germany)
S. Schrader, Univ. of Applied Sciences (Germany)
O. Tolmachev, Institute of Organic Chemistry (Ukraine)
Yu. Slominskii, Institute of Organic Chemistry (Ukraine)
V. Kurdiukov, Institute of Organic Chemistry (Ukraine)
G. Smirnova, Institute of Organic Chemistry (Ukraine)
V. Ksianzou, Univ. of Applied Sciences (Germany)
S. Schrader, Univ. of Applied Sciences (Germany)
O. Tolmachev, Institute of Organic Chemistry (Ukraine)
Yu. Slominskii, Institute of Organic Chemistry (Ukraine)
V. Kurdiukov, Institute of Organic Chemistry (Ukraine)
G. Smirnova, Institute of Organic Chemistry (Ukraine)
Published in SPIE Proceedings Vol. 6999:
Organic Optoelectronics and Photonics III
Paul L. Heremans; Michele Muccini; Eric A. Meulenkamp, Editor(s)
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