Grażyna Wójcik scite author profile

The meta-dinitrobenzene crystal structure has been determined at five temperatures in the 100-300 K temperature range. The thermal expansion coefficients have been calculated from the temperature variation of the lattice parameters. Rigid-body motion analysis with allowance for large-amplitude internal motions provided the T, L and S tensors' values at the temperatures studied and was used to characterize the torsional motion of two nitro groups in the molecule. Frequencies of the translational and librational modes and of the torsional modes of the nitro groups have been compared with the wave numbers at the maximum of bands in the low-frequency Raman and IR spectra. Ab initio calculations were performed in order to assess the contribution from large-amplitude internal motions to the static first-order hyperpolarizability of the m-dinitrobenzene molecule.

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Electrochemical behavior of lead in sulfuric acid solutions

Czerwiński

Żelazowska

Grdeń

et al. 2000

Journal of Power Sources

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Electron-density study of m-nitrophenol in the orthorhombic structure

Hamzaoui¹,

Baert²,

Wójcik³

1996

Acta Crystallogr Sect B

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m-Nitrophenol (m-NPH) occurs at room temperature in two solid modifications: monoclinic P21/n and orthorhombic P212121 [Pandarese, Ungaretti & Coda (1975).Acta Cryst. B31, 2671-2675]. The thermal vibrations and electronic-density distribution of the molecule in the orthorhombic structure have been analyzed in terms of Stewart's rigid pseudoatom model, using restricted Slater radial functions and angular multipole terms extending to actapoles for C, N and O and dipoles for H pseudoatoms. The net atomic charge and the in-crystal molecular dipole moment have been determined in order to understand the nature of the inter-and intramolecular charge transfer. The analysis suggests that aspherical pseudoatoms are essential for modeling the charge distribution in a noncentrosymmetric crystal. Careful consideration must also be given to the treatment of the H atoms, in the absence of complementary neutron diffraction data. ExperimentalThe purification of the material and the crystal growing were published earlier (Wojcik & Marqueton, 1989) and the experimental details and crystal data are given in Table 1. X-ray intensity data were measured on a CAD-4 diffractometer using graphite-monochromated MoKt~ radiation (50kV, 35 mA). A crystal of high quality was cooled by a stream of cold nitrogen gas. Lattice constants were determinated by a least-squares fit of setting angles for 25 well centered reflections in the range 11 _< 0 _< 25 °. The profiles of the different reflections were measured using the 0-20 step scan method. Three standard reflections were measured every 2h, the corresponding linear decay correction was performed but nonsignificant variation was observed and the obtained instrumental factor was 0.015. The intensities were measured only once with a relatively slow speed of 1.02 ° min -~. A total of 2224 intensities were collected and merged to give 2004 independent reflections. The internal agreement for all equivalent reflections was 0.02 (in reality only the standard references were measured more times). As a preliminary check on the X-ray intensity data, the atomic positions were obtained by a

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