A Simulated Annealing Approach for Crystal Structure Solution from Powder Diffraction Data

Recent advances in crystallographic computing and availability of high-resolution diffraction data have made it relatively easy to solve crystal structures from powders that would have traditionally required single crystal samples. The success of direct space methods depends heavily on starting with

The ordered, low-temperature crystal structure of the pure enantiomer of camphor (C 10 H 16 O) has been solved from highresolution powder synchrotron X-ray di4raction data. The structure is orthorhombic, space group P2 1 2 1 2 1 , Z ‫؍‬ 8, with a ‫؍‬ 8.9277(2) A s , b ‫؍‬ 27.0359(5) A s , and c ‫؍‬

The crystal structure of silicon pyrophosphate (Form I) was solved from \(X\)-ray powder data and refined by the Rietveld method. The crystals belong to the hexagonal space group \(P \boldsymbol{6}_{3}\) with \(a=\) 4.7158(3) \(\AA\) and \(c=11.917(1) \AA\). There are two \(\mathrm{SiP}_{2} \mathrm{

## Abstract Previously, the genetic algorithm (GA) approach for direct‐space crystal structure solution from powder diffraction data has been applied successfully in the structure determination of a range of organic molecular materials. In this article, we present a further development of our appro