This paper describes a method for the laboratory-scale crystallization of the orthorhombic polymorph (form II) of paracetamol (acetaminophen) from solution. Its structure has been determined by single-crystal X-ray crystallography at 298 K (to confirm the results of data published in 1974) and at 123 K (to improve the overall accuracy of the structure determination). Despite considerable effort by many investigators, the crystallization of form II from solution, using the method given in the 1974 structure report, has been elusive. The incentive for this effort is that form II, unlike commercial paracetamol (form I), undergoes plastic deformation and is suitable for direct compression. Consequently, the ability to produce form II in quantity has attracted much interest because of the potential commercial benefits to be gained by not using binders during the manufacture of tablets. However, until now, the only method that has been reported for the bulk preparation of form II has been to grow it as polycrystalline material from fused form I. This study also compares the solid-state properties of form II with those of form I, with particular emphasis on the crystallography (both X-ray and optical), crystal morphology, thermal behavior, and compaction properties.
The crystal structures of 35 molecular compounds have been redetermined from laboratory monochromatic capillary transmission X-ray powder diffraction data using the simulated-annealing approach embodied within the DASH structure solution package. The compounds represent industrially relevant areas (pharmaceuticals; metal coordination compounds; nonlinear optical materials; dyes) in which the research groups in this multi-centre study are active. The molecules were specifically selected to form a series within which the degree of structural complexity (i.e. degrees of freedom in the global optimization) increased systematically, the degrees of freedom increasing with increasing number of optimizable torsion angles in the structural model and with the inclusion of positional disorder or multiple fragments (counterions; crystallization solvent; Z 0 > 1). At the lower end of the complexity scale, the structure was solved with excellent reproducibility and high accuracy. At the opposite end of the scale, the more complex search space offered a significant challenge to the global optimization procedure and it was demonstrated that the inclusion of modal torsional constraints, derived from the Cambridge Structural Database, offered significant benefits in terms of increasing the frequency of successful structure solution by restricting the magnitude of the search space in the global optimization.
Palladium complexes of 1,3,5,7-tetramethyl-2,4,8-trioxa-6-phenyl-6-phosphaadamantane were prepared and characterized with Pd[1,3,5,7-tetramethyl-2,4,8-trioxa-6-phenyl-6-phosphaadamantane](2).dba shown to be an effective catalyst for use in the Suzuki and Sonogashira reactions and the alpha-arylation of ketones. Couplings using this versatile complex proceeded in excellent yields under mild conditions.
The in-crystal molecular dipole moment of the nonlinear optical material 2-methyl-4-nitroaniline has been determined from a charge density analysis of x-ray diffraction data. The results indicate a considerable enhancement of the free molecule dipole moment, due to the crystal field. 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 hydrogen atoms, in the absence of complementary neutron diffraction data. An analysis of the deformation density and Laplacian of the charge density proves useful for revealing weak hydrogen bonding effects. Ab initio calculations at the Hartree-Fock double-zeta level are reported for the molecule 2-methyl-4-nitroaniline, with and without an applied electric field. In the former case, the magnitude and direction of the applied field were determined by a dipole lattice sum, to assess the magnitude of crystal field effects. The effect was to considerably enhance the molecular dipole moment, from 9 to 20 D, in agreement with the experimentally observed enhancement. Structure factors were generated from the ab initio wave functions and subjected to multipole refinement, to effectively project the theoretical rho(r) into the same atom-centered multipole expansion form obtained from experiment. Monopole and dipole populations obtained in this way show convincing agreement with experiment
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