The role of nano-perovskite in the negligible thorium release in seawater from Greek bauxite residue (red mud)

We present new data about the chemical and structural characteristics of bauxite residue (BR) from Greek Al industry, using a combination of microscopic, analytical, and spectroscopic techniques. SEM-EDS indicated a homogeneous dominant “Al-Fe-Ca-Ti-Si-Na-Cr matrix”, appearing at the microscale. The bulk chemical analyses showed considerable levels of Th (111 μg g−1), along with minor U (15 μg g−1), which are responsible for radioactivity (355 and 133 Bq kg−1 for 232Th and 238U, respectively) with a total dose rate of 295 nGy h−1. Leaching experiments, in conjunction with SF-ICP-MS, using Mediterranean seawater from Greece, indicated significant release of V, depending on S/L ratio, and negligible release of Th at least after 12 months leaching. STEM-EDS/EELS & HR-STEM-HAADF study of the leached BR at the nanoscale revealed that the significant immobility of Th4+ is due to its incorporation into an insoluble perovskite-type phase with major composition of Ca0.8Na0.2TiO3 and crystallites observed in nanoscale. The Th LIII-edge EXAFS spectra demonstrated that Th4+ ions, which are hosted in this novel nano-perovskite of BR, occupy Ca2+ sites, rather than Ti4+ sites. That is most likely the reason of no Th release in Mediterranean seawater

6li 28si reaction cross sections at sub barrier energies

Total reaction cross sections at near barrier energies (9-13 MeV) were measured for the system 6Li+28Si adopting a new technique. The results will be discussed in terms of the threshold anomaly at barrie

Hydroxypropyl Methylcellulose as a Novel Tool for Isothermal Solution Crystallization of Micronized Paracetamol

This document is the Accepted Manuscript version of a Published Work that appeared in final form in Crystal Growth and Design, copyright © American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see: http://pubs.acs.org/doi/abs/10.1021/cg4009637Pulmonary inhalation is increasingly being selected as a preferred route for the delivery of both small and large drug macromolecules for the treatment of a range of pathologies. The direct crystallization of micronized powders, in particular, paracetamol, remains difficult, as it requires the ability to work in high solution supersaturations where agglomeration, wall crusting, and heterogeneous nucleation hinder the control of crystal size and crystal size distribution. Polymer additives are recognized to help drive the production of a given polymorph or controlling crystal shape by means of adsorption on the crystal surface. With the aim of exploiting the polymer-control nucleation and growth of crystals for enhanced direct crystallization of micronized powders, batch cooling crystallization of paracetamol in water was carried out in the presence of 0.1-0.8% w/w hydroxypropyl methylcellulose (HPMC). In the presence of polymer, the onset of nucleation was delayed and extended beyond the cooling time of the solution, resulting in an isothermal cooling crystallization and the production of micronized paracetamol with a mean crystal size D50, in the range of 15-20 μm and an improved crystal size distribution. Equally, the rate generation of solution cloudiness was reduced by over 3-fold for the highest HPMC concentration tested, with no detectable impact on final product yield. The mechanisms for nucleation delay and growth inhibition by HPMC is unknown; however, a modification of crystals shape observed upon the addition of HPMC to the solution suggested it might be related to mass transfer limitations and intermolecular hydrogen bonding between the large HPMC and the small drug molecules. This technique can potentially be used for direct crystallization of other micronized drugs. © 2014 American Chemical Society