An elementary treatment on the diffraction of crystalline structures

Although W. L. Bragg's law can be easily derived for beginners in the field of crystallography, its interpretation however seems to cause some difficulties which lies essentially in the relation between the concept of lattice planes and the unit cell constants characterizing the lattice periodicity of the crystal structure. Our approach is certainly not new and is based on a more physical approach where every single point in the crystal participates in the diffraction process. From the early stages of developing a model of diffraction, we make abundant use the dual reference frames namely the direct and reciprocal reference frames. With this approach, W. L. Bragg's law can be reformulated directly in terms of the reciprocal unit cell constants avoiding thus the necessity to introduce a priori the notion of lattice planes. Following the derivation of the diffraction law, different steps and methods leading to the complete determination of a crystal structure are derived. We present also some simulation tools to explain in particular the crystal diffraction phenomenon based on the Ewald sphere and the solution of crystalline structures based on the dual space iteration techniques which are currently used.

Simulations d'une structure cristalline incommensurable à caractère désordonné

Eric Germaneau

Incommensurate crystal structures do not display three-dimensional periodicity. Discovered in the 1960's, a mathematical model has been established in 1974 only. Incommensurate structures belong to the big family of aperiodic structures. The modulation of incommensurate structures manifests itself as satellite reflections around the main peaks on X-rays diffractograms. Short range order correlations in crystals lead to diffuse scattering between Bragg peaks in the diffraction pattern. The computing power available today allows for very time consuming simulations of the incommensurate or disordered crystal structures. Simulations based on Monte-Carlo and the molecular dynamic techniques have been performed. The former is based on stochastic algorithms, whereas the latter is deterministic. This PhD thesis strove to combine these two methods, using a four-isomermodel, in order to study the incommensurate, disordered polymorph of p-azoxydiphenetol (PAP), which crystallises below 356 K. One of the main features of the PAP molecule is its dative bond. A Monte-Carlo program, using true empirical potentials, has been developed in order to explain the behaviour of PAP. This code (6000 lines), written in C, uses the GSL and OpenMP libraries. Using numerical and experimental tools, this thesis provides explanations for the origin, from an atomic point of view, of the incommensurate and disordered behaviour of PAP. Calculations have been performed on the clusters of École Polytechnique Fédérale de Lausanne. Simulated diffraction patterns have been compared to experimental data, collected before and during this study. Moreover, a set of differential scanning calorimetry (DSC) measurements has been carried out during this work, the results of which have been analysed based on Arrhenius's law. For a better understanding of the role played by the dative bond, and the relation between the complexity of the molecule and the structure, DFT and ab initio calculations have been performed. This work has successfully woven the results from different experimental and numerical techniques into a comprehensive model for this very complex system indeed.

EPFL2008

Simulations d'une structure cristalline incommensurable à caractère désordonné

Eric Germaneau

EPFL2008