The structure of the double perovskite Sr₂CaWO₆ has been refined using X-ray single-crystal data. Samples have been grown by sintering at high temperature. The model includes a quantitative description of the twinning expected for these compounds.

A unified description for structures in the homologous series Ga₂O₃(ZnO)_m is presented using the superspace formalism. The structures of phases m = 6 and m = 9 were refined using the proposed model.

The MEM provides a description of the atomic modulations within the ordered and disordered regions of incommensurate Cr₂P₂O₇, from its application to X-ray diffraction data of this compound.

The structure of Ga₄B₂O₉ is solved from powder X-ray diffraction data and refined by Rietveld analysis. The order–disorder phenomenon in the structure is elucidated by the construction of the fundamental building units.

The structures of two new synthetic silicates based on a rhodesite-type heteropolyhedral framework are reported and peculiar microporous features of the group are discussed.

The crystal chemical features of heteropolyhedral microporous silicates A₃RESi₆O₁₅·2.25H₂O (A = Na, K, H₃O; RE = rare earths La, Ce, Eu) based on 4¹5¹6¹8² tetrahedral sheets are discussed.

The crystal structure of the floating-zone furnace-grown crystal Bi_35.66W_4.34O_66.51 was determined from simultaneous refinements against single-crystal neutron and synchrotron X-ray data.

Analysis of the 62 entries under the polar space group P31m listed in the ICSD release 2009/1 reveals that 11 of the 31 crystallographic families present are candidates for possessing the property of ferroelectricity. New among them are the minerals schairerite, galeite and lizardite in addition to the materials LaNi₅D₆, [N(CH₃)₄]₂Mo₃S₁₃, Li₁₇Ag₃Sn₆ and Cs₃As₅O₉.

Disorder in α-Rb₂[C₂O₄] and α-Rb₂[CO₃] is studied by the application of the maximum entropy method (MEM) to X-ray powder diffraction data, employing phases of reflections from various sources. The MEM applied to reflection phases from charge-flipping combined with amplitudes from a Le Bail extraction provide an ab initio description of the structural disorder in these compounds.

The neutral diethyl 4,4′-(ferrocene-1,1′-diyl)dibenzoate, 1,1′-Fc(4-C₆H₄CO₂Et)₂ [1,1′-Fc = η⁵-(C₅H₄)₂Fe], yields the complex salt with Z′ = 5, poly[disodium bis[diethyl 4,4′-(ferrocene-1,1′-diyl)dibenzoate] 0.6-hydrate], poly-[Na⁺]₂[η⁵-(C₅H₄)₂Fe(4-C₆H₄CO)₂]·0.6H₂O, crystallized with difficulty as small red crystals over 4 weeks from a water/dimethylformamide/pyridine (2:2:1) solution. The asymmetric unit as poly-[Na⁺]₁₀[η⁵-(C₅H₄)₂Fe(4-C₆H₄CO)₂]₅·3H₂O comprises five dianions stacked about a central two-dimensional layer of ten Na⁺ ions and three water molecules.

The complex [Cu(L^OH)₂][ClO₄]₂·2(CH₃)₂CO [L^OH = 2,6-bis(hydroxyiminomethyl)pyridine] undergoes an abrupt structural rearrangement on cooling to 157 ±3 K. This involves a change in the Jahn–Teller distortion of the complex, a crystallographic ordering of a perchlorate ion, and significant displacements of the two lattice acetone molecules.

Five co-crystals grown from aqueous solutions equimolar in 15-crown-5 and [M(H₂O)₆](NO₃)_n, M = Al³⁺, Cr³⁺ and Pd²⁺, all contain hydrogen-bonded stacks in which metal complexes containing the fragment trans-H₂O—M—OH₂ alternate with 15-crown-5 molecules. A survey of the literature found 41 structures containing similar stacks.

The proton-transfer mechanism cannot be described as strictly simultaneous or successive as situations close to both of these scenarios were observed.

The crystal structures of tetramethylsilane, Si(CH₃)₄, and tetramethylgermane, Ge(CH₃)₄, were predicted by global lattice-energy minimizations. For tetramethylsilane, a low-temperature structure at 100 K could be determined from single-crystal X-ray diffraction data.

A complete exploration of intramolecular hydrogen bonds (IHBs) has been undertaken using a combination of statistical analyses of the Cambridge Structural Database and computation of ab initio interaction energies for prototypical hydrogen-bonded fragments. The findings contribute to a new method to predict IHB likelihood in generic organic crystal structures. Predictivity in excess of 90% has been obtained.

The two closely related polymorphs of L-aminobutyric acid are divided into hydrophilic layers and hydrophobic layers, the latter being exceptionally thin with unique pseudo-centers-of-symmetry.

A Monte Carlo computer model has been developed for the room-temperature form (II) polymorph of benzocaine that incorporates, on a local scale, structural features derived from the low-temperature form (III) polymorph. This convincingly reproduces those observed diffraction features that an earlier simple harmonic model was unable to achieve.