Your search keyword '"Konôpková, Z."' showing total 2 results

1. Structural study of helical polyfluorene under high quasihydrostatic pressure.

Author

Knaapila, M., Konôpková, Z., Torkkeli, M., Haase, D., Liermann, H.-E., Guha, S., and Scherf, U.

Subjects

*X-ray diffraction, *X-ray scattering, *DEFORMATIONS (Mechanics), *POLYFLUORENES, *HYDROSTATICS, *PHOTOLUMINESCENCE

Abstract

We report on an x-ray diffraction (XRD) study of helical poly[9,9-bis(2-ethylhexyl)fluorene] (PF2/6) under high quasihydrostatic pressure and show an effect of pressure on the torsion angle (dihedral angle) between adjunct repeat units and on the hexagonal unit cell. A model for helical backbone conformation is constructed. The theoretical position for the most prominent 001 x-ray reflection is calculated as a function of torsion angle. The XRD of high molecular weight PF2/6 (Ma = 30 kg/mol) is measured through a diamond anvil cell upon pressure increase from 1 to 10 GPa. The theoretically considered 001 reflection is experimentally identified, and its shift with the increasing pressure is found to be consistent with the decreasing torsion angle between 2 and 6 GPa. This indicates partial backbone planarization towards a more open helical structure. The h00 peak is identified, and its shift together with the broadening of 00l implies impairment of the ambient hexagonal order, which begins at or below 2 GPa. Previously collected high-pressure photoluminescence data are reanalyzed and are found to be qualitatively consistent with the XRD data. This paper provides an example of how the helical 7r-conjugated backbone structure can be controlled by applying high quasihydrostatic pressure without modifications in its chemical structure. Moreover, it paves the way for wider use of high-pressure x-ray scattering in the research of Π-conjugated polymers. [ABSTRACT FROM AUTHOR]

Published

2013

2. High-pressure synthesis and characterization of iridium trihydride.

Author

Scheler T, Marqués M, Konôpková Z, Guillaume CL, Howie RT, and Gregoryanz E

Abstract

We have performed in situ synchrotron x-ray diffraction studies of the iridium-hydrogen system up to 125 GPa. At 55 GPa, a phase transition in the metal lattice from the fcc to a distorted simple cubic phase is observed. The new phase is characterized by a drastically increased volume per metal atom, indicating the formation of a metal hydride, and substantially decreased bulk modulus of 190 GPa (383 GPa for pure Ir). Ab initio calculations show that the hydrogen atoms occupy the face-centered positions in the metal matrix, making this the first known noninterstitial noble metal hydride and, with a stoichiometry of IrH(3), the one with the highest volumetric hydrogen content. Computations also reveal that several energetically competing phases exist, which can all be seen as having distorted simple cubic lattices. Slow kinetics during decomposition at pressures as low as 6 GPa suggest that this material is metastable at ambient pressure and low temperatures.

Published

2013