Cation nonstoichiometry in tin-monoxide-phase Sn1-dO with tweed microstructure

M.S. MORENO; A. VARELA; L.C. OTERO-DÍAZ

PHYSICAL REVIEW B - CONDENSED MATTER AND MATERIALS PHYSICS

American Physical Society

Año: 1997 vol. 56 p. 5186 - 5192

0163-1829

We report a chemical, thermogravimetric, and electron-diffraction/microscopy study of a tin-monoxide phase. A large deviation from the ideal stoichiometry is observed due to metal vacancies, resulting in the formula Sn1-dO. This nonstoichiometry is an intrinsic feature of this material and is accommodated through the formation of static transverse displacive modulations along the <hh0> directions, giving a tweed microstructure without the introduction of complex arrangements of vacancy interstitials (as in wustite). Our observation constitutes a different way of accommodating large deviations from ideal stoichiometries, especially incomparison with the well-known behavior of the transition-metal monoxides with the NaCl-type structure. Thedifference arises most likely from the layerlike nature of the a-PbO (B-10) structural type with average tetragonal symmetry and P4/nmm space group. Metal vacancies cause a strain coupling which stabilizes the highly disordered nonstoichiometric phase. Dynamical instabilities were not observed. An origin for the thermal instability of the material is suggested. A comparison with PbO, the only isostructural compound, is outlined. SnO is shown to be a beam-sensitive material.