The bjarebyite group of minerals, characterized by the general formula BaX₂Y₂(PO₄)₃(OH)₃, with X = Mg, Fe²⁺ or Mn²⁺, and Y = Al or Fe³⁺, includes five members: bjarebyite BaMn²⁺₂Al₂(PO₄)₃(OH)₃, johntomaite BaFe²⁺₂Fe³⁺₂(PO₄)₃(OH)₃, kulanite BaFe²⁺₂Al₂(PO₄)₃(OH)₃, penikisite BaMg₂Al₂(PO₄)₃(OH)₃, and perloffite BaMn²⁺₂Fe³⁺₂(PO₄)₃(OH)₃. Thus far, the crystal structures of all minerals in the group, but penikisite, have been determined. The present study reports the first structure determination of penikisite (barium dimagnesium dialuminium triphosphate trihydroxide) using single-crystal X-ray diffraction data of a crystal from the type locality, Mayo Mining District, Yukon Territory, Canada. Penikisite is isotypic with other members of the bjarebyite group with space group P2₁/m, rather than triclinic (P1 or P-1), as previously suggested. Its structure consists of edge-shared [AlO₃(OH)₃] octa­hedral dimers linking via corners to form chains along [010]. These chains are decorated with PO₄ tetra­hedra (one of which has site symmetry m) and connected along [100] via edge-shared [MgO₅(OH)] octa­hedral dimers and eleven-coordinated Ba²⁺ ions (site symmetry m), forming a complex three-dimensional network. O—HO hydrogen bonding provides additional linkage between chains. Microprobe analysis of the crystal used for data collection indicated that Mn substitutes for Mg at the 1.5% (apfu) level.

This report presents the first crystal structure determination of the mineral schaurteite, ideally Ca₃Ge(SO₄)₂(OH)₆·3H₂O, tricalcium germanium bis­(sulfate) hexa­hydroxide trihydrate. This single-crystal X-ray diffraction study investigated a natural sample from the type locality at Tsumeb, Namibia. Schaurteite is a member of the fleischerite group of minerals, which also includes fleischerite, despujolsite, and mallestigite. The structure of schaurteite consists of slabs of Ca(O,OH,H₂O)₈ polyhedra (site symmetry mm2) inter­leaved with a mixed layer of Ge(OH)₆ octa­hedra (-3m.) and SO₄ tetra­hedra (3m.). There are two H atoms in the asymmetric unit, both located by full-matrix refinement, and both forming O—HO hydrogen bonds.

Pirquitasite, ideally Ag₂ZnSnS₄ (disilver zinc tin tetra­sulfide), exhibits tetra­gonal symmetry and is a member of the stannite group that has the general formula A₂BCX₄, with A = Ag, Cu; B = Zn, Cd, Fe, Cu, Hg; C = Sn, Ge, Sb, As; and X = S, Se. In this study, single-crystal X-ray diffraction data are used to determine the structure of pirquitasite from a twinned crystal from the type locality, the Pirquitas deposit, Jujuy Province, Argentina, with anisotropic displacement parameters for all atoms, and a measured composition of (Ag_1.87Cu_0.13)(Zn_0.61Fe_0.36Cd_0.03)SnS₄. One Ag atom is located on Wyckoff site Wyckoff 2a (symmetry -4..), the other Ag atom is statistically disordered with minor amounts of Cu and is located on 2c (-4..), the (Zn, Fe, Cd) site on 2d (-4..), Sn on 2b (-4..), and S on general site 8g. This is the first determination of the crystal structure of pirquitasite, and our data indicate that the space group of pirquitasite is I-4, rather than I-42m as previously suggested. The structure was refined under consideration of twinning by inversion [twin ratio of the components 0.91 (6):0.09 (6)].

Lanthanite-(Nd), ideally Nd₂(CO₃)₃·8H₂O [dineodymium(III) tricarbonate octa­hydrate], is a member of the lanthanite mineral group characterized by the general formula REE₂(CO₃)₃·8H₂O, where REE is a 10-coordinated rare earth element. Based on single-crystal X-ray diffraction of a natural sample from Mitsukoshi, Hizen-cho, Karatsu City, Saga Prefecture, Japan, this study presents the first structure determination of lanthanite-(Nd). Its structure is very similar to that of other members of the lanthanite group. It is composed of infinite sheets made up of corner- and edge-sharing of two NdO₁₀-polyhedra (both with site symmetry ..2) and two carbonate triangles (site symmetries ..2 and 1) parallel to the ab plane, and stacked perpendicular to c. These layers are linked to one another only through hydrogen bonding involving the water mol­ecules.

The crystal structure of katayamalite, ideally KLi₃Ca₇Ti₂(SiO₃)₁₂(OH)₂ (potassium trilithium hepta­calcium dititanium dodeca­silicate di­hydroxide), was previously reported in triclinic symmetry (C-1), with isotropic displacement parameters for all atoms and without the H-atom position [Kato & Murakami (1985). Mineral. J. 12, 206-217]. The present study redetermines the katayamalite structure with monoclinic symmetry (space group C2/c) based on single-crystal X-ray diffraction data from a sample from the type locality, Iwagi Island, Ehime Prefecture, Japan, with anisotropic displacement parameters for all non-H atoms, and with the H atoms located by difference Fourier analysis. The structure of katayamalite contains a set of six-membered silicate rings inter­connected by sheets of Ca atoms on one side and by an ordered mixture of Li, Ti and K atoms on the other side, forming layers which are stacked normal to (001). From the eight different metal sites, three are located on special positions, viz. one K and one Li atom on twofold rotation axes and one Ca atom on an inversion center. The Raman spectrum of kataymalite shows a band at 3678 cm^-1, similar to that observed for hydroxyl-amphiboles, indicating no or very weak hydrogen bonding.

Agardite-(Y), with a refined formula of Cu²⁺_5.70(Y_0.69Ca_0.31)[(As_0.83P_0.17)O₄]₃(OH)₆·3H₂O [ideally Cu²⁺₆Y(AsO₄)₃(OH)₆·3H₂O, hexa­copper(II) yttrium tris­(arsenate) hexa­hydroxide trihydrate], belongs to the mixite mineral group which is characterized by the general formula Cu²⁺₆A(TO₄)₃(OH)₆·3H₂O, where nine-coordinated cations in the A-site include rare earth elements along with Al, Ca, Pb, or Bi, and the T-site contains P or As. This study presents the first structure determination of agardite-(Y). It is based on the single-crystal X-ray diffraction of a natural sample from Jote West mine, Pampa Larga Mining District, Copiapo, Chile. The general structural feature of agardite-(Y) is characterized by infinite chains of edge-sharing CuO₅ square pyramids (site symmetry 1) extending down the c axis, connected in the ab plane by edge-sharing YO₉ polyhedra (site symmetry -6..) and corner-sharing AsO₄ tetra­hedra (site symmetry m..). Hy­droxyl groups occupy each corner of the CuO₅-square pyramids not shared by a neighboring As or Y atom. Each YO₉ polyhedron is surrounded by three tubular channels. The walls of the channels, parallel to the c axis, are six-membered hexa­gonal rings comprised of CuO₅ and AsO₄ polyhedra in a 2:1 ratio, and contain free mol­ecules of lattice water.