Crystal structure, hydrogen bonding, mechanical properties and Raman spectrum of the lead uranyl silicate monohydrate mineral kasolite

Francisco Colmenero; Jakub Plášil; Joaquín Cobos; Jiří Sejkora; Vicente Timón; Jiří Čejka; Laura J Bonales

doi:10.1039/c9ra02931a

Crystal structure, hydrogen bonding, mechanical properties and Raman spectrum of the lead uranyl silicate monohydrate mineral kasolite

RSC Adv. 2019 May 16;9(27):15323-15334. doi: 10.1039/c9ra02931a. eCollection 2019 May 14.

Authors

Francisco Colmenero¹, Jakub Plášil², Joaquín Cobos³, Jiří Sejkora⁴, Vicente Timón¹, Jiří Čejka⁴, Laura J Bonales³

Affiliations

¹ Instituto de Estructura de la Materia (IEM-CSIC) C/ Serrano, 113 28006 Madrid Spain francisco.colmenero@iem.cfmac.csic.es.
² Institute of Physics ASCR, v.v.i. Na Slovance 2 182 21 Praha 8 Czech Republic.
³ Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas (CIEMAT) Avda/Complutense, 40 28040 - Madrid Spain.
⁴ Mineralogicko-Petrologické Oddělení, Národní Muzeum Cirkusová 1740 193 00 Praha 9 Czech Republic.

Abstract

The crystal structure, hydrogen bonding, mechanical properties and Raman spectrum of the lead uranyl silicate monohydrate mineral kasolite, Pb(UO₂)(SiO₄)·H₂O, are investigated by means of first-principles solid-state methods based on density functional theory using plane waves and pseudopotentials. The computed unit cell parameters, bond lengths and angles and X-ray powder pattern of kasolite are found to be in very good agreement with their experimental counterparts. The calculated hydrogen atom positions and associated hydrogen bond structure in the unit cell of kasolite confirmed the hydrogen bond scheme previously determined from X-ray diffraction data. The kasolite crystal structure is formed from uranyl silicate layers having the uranophane sheet anion-topology. The lead ions and water molecules are located in the interlayer space. Water molecules belong to the coordination structure of lead interlayer ions and reinforce the structure by hydrogen bonding between the uranyl silicate sheets. The hydrogen bonding in kasolite is strong and dual, that is, the water molecules are distributed in pairs, held together by two symmetrically related hydrogen bonds, one being directed from the first water molecule to the second one and the other from the second water molecule to the first one. As a result of the full structure determination of kasolite, the determination of its mechanical properties and Raman spectrum becomes possible using theoretical methods. The mechanical properties and mechanical stability of the structure of kasolite are studied using the finite deformation technique. The bulk modulus and its pressure derivatives, the Young and shear moduli, the Poisson ratio and the ductility, hardness and anisotropy indices are reported. Kasolite is a hard and brittle mineral possessing a large bulk modulus of the order of B ∼ 71 GPa. The structure is mechanically stable and very isotropic. The large mechanical isotropy of the structure is unexpected since layered structures are commonly very anisotropic and results from the strong dual hydrogen bonding among the uranyl silicate sheets. The experimental Raman spectrum of kasolite is recorded from a natural mineral sample from the Jánská vein, Příbram base metal ore district, Czech Republic, and determined by using density functional perturbation theory. The agreement is excellent and, therefore, the theoretical calculations are employed to assign the experimental spectrum. Besides, the theoretical results are used to guide the resolution into single components of the bands from the experimental spectrum. A large number of kasolite Raman bands are reassigned. Three bands of the experimental spectrum located at the wavenumbers 1015, 977 and 813 cm^-1, are identified as combination bands.