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Guangyuanite, Pb3Cl3(Se4+O3)(OH), a new lead chloride selenite mineral from the El Dragón mine, Potosí, Bolivia

Published online by Cambridge University Press:  07 December 2023

Hexiong Yang Open the ORCID record for Hexiong Yang [Opens in a new window] ,
Xiangping Gu Open the ORCID record for Xiangping Gu [Opens in a new window] ,
James A. McGlasson ,
Ronald B. Gibbs  and
Robert T. Downs
Hexiong Yang*
Affiliation:
Department of Geosciences, University of Arizona, 1040 E. 4th Street, Tucson, AZ 85721-0077, USA
Xiangping Gu
Affiliation:
School of Geosciences and Info-Physics, Central South University, Changsha, Hunan 410083, China
James A. McGlasson
Affiliation:
Department of Geosciences, University of Arizona, 1040 E. 4th Street, Tucson, AZ 85721-0077, USA
Ronald B. Gibbs
Affiliation:
Department of Geosciences, University of Arizona, 1040 E. 4th Street, Tucson, AZ 85721-0077, USA
Robert T. Downs
Affiliation:
Department of Geosciences, University of Arizona, 1040 E. 4th Street, Tucson, AZ 85721-0077, USA
*
Corresponding author: Hexiong Yang; Email: hyang@arizona.edu
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Abstract

A new mineral species, guangyuanite, ideally Pb3Cl3(Se4+O3)(OH), was discovered from the El Dragón mine, Antonio Quijarro Province, Potosí Department, Bolivia. It occurs as equant crystals. Associated minerals are Co-bearing krut'aite–penroseite, chalcomenite, schmiederite, olsacherite, phosgenite, anglesite, cerussite and franksousaite. Guangyuanite is pale yellow–brown in transmitted light, transparent with white streak and vitreous lustre. It is brittle and has a Mohs hardness of ~3. No parting or cleavage was observed. The calculated density is 7.63 g/cm3. An electron microprobe analysis yielded an empirical formula [based on 7 (O + Cl) atoms per formula unit] of Pb3.02Cl3.01(Se4+0.99O3)(OH), which can be simplified to Pb3Cl3(Se4+O3)(OH).

Guangyuanite is isostructural with synthetic Pb3Br3(Se4+O3)(OH). It is orthorhombic, with space group Pnma and unit-cell parameters a = 11.0003(5), b = 10.6460(5), c = 7.7902 Å, V = 912.31(6) Å3 and Z = 4. The crystal structure of guangyuanite contains two symmetrically-distinct Pb (Pb1 and Pb2) cations, with Pb1 coordinated by eight anions (4O + 4Cl) and Pb2 only by six anions (3O + 3Cl), forming a marked lopsided coordination typical of Pb2+ with a stereochemically active 6s2 lone electron pair. The Se4+ cation forms a typical [Se4+O3] trigonal pyramid. The crystal structure of guangyuanite can be described as consisting of layers of edge-sharing [Pb1O4Cl4] polyhedra parallel to (100). These layers are linked together by sharing polyhedral corners (Cl atoms), as well as [Pb2O3Cl3] and [Se4+O3] groups. Chemically, guangyuanite is one of six lead chloride selenite minerals reported thus far and closely related to orlandiite Pb3Cl4(Se4+O3)⋅H2O.

Keywords

guangyuanitelead selenite chloridenew mineralcrystal structureRamanEl Dragón mineBolivia
Type
Article
Information
Mineralogical Magazine , Volume 88 , Issue 1 , February 2024 , pp. 97 - 104
Copyright
Copyright © University of Arizona, 2023. Published by Cambridge University Press on behalf of The Mineralogical Society of the United Kingdom and Ireland

Introduction

Guangyuanite, ideally Pb3Cl3(Se4+O3)(OH), is a new mineral species discovered from the El Dragón mine, Antonio Quijarro Province, Potosí Department, Bolivia. It is named in honour of the late Chinese mineralogist, Prof. Chen Guangyuan (1920–1999). Prof. Chen obtained his Degree of Licentiate from the Uppsala University of Sweden in 1951 and became a teacher and researcher at Peking University between 1951 and 1952 and later at the China University of Geosciences in Beijing from 1952 to 1999. Prof. Chen is regarded as the pioneer and leader for both teaching and research in genetic and exploration mineralogy in China from the 1950's to 1980's. He made significant contributions to the systematic studies of the genesis of minerals, especially on genetic classification of mineral groups, typomorphic mineralogy, and mineralogical mapping for exploration, with over 100 publications and 9 books, including the well-recognised “Genetic Mineralogy and Prospecting Mineralogy”, which has been adopted by many universities in China. The new mineral and its name (symbol Gyn) have been approved by the Commission on New Minerals, Nomenclature and Classification (CNMNC) of the International Mineralogical Association (IMA 2022-124, Yang et al., Reference Yang, Gu, McGlasson and Gibbs2023d). The co-type samples have been deposited at the University of Arizona Alfie Norville Gem and Mineral Museum (Catalogue # 22714) and the RRUFF Project (deposition # R210013) (http://rruff.info) (Lafuente et al., Reference Lafuente, Downs, Yang, Stone, Armbruster and Danisi2015).

Lead chloride selenite minerals are rather rare in Nature and only six minerals contain Pb–Cl–(Se4+O3)2– in the current IMA-approved mineral list (Table 1). Interestingly, all of these minerals have only been described in the past 25 years. Nevertheless, synthetic lead chloride selenite materials have been an attractive subject in numerous investigations. On the one hand, selenite materials can form a diversity of unusual structures due to the presence of the stereochemically active lone-pair electrons in Se4+, which can serve as structure-directing agents (Berdonosov et al., Reference Berdonosov, Stefanovitch and Dolgikh2000, Reference Berdonosov, Olenev and Dolgikh2012; Wickleder, Reference Wickleder2002 and references therein). The lone-pair electrons in Se4+ are not involved in the formation of chemical bonds, thus acting like terminal ligands and resulting in various voids in the structure. Furthermore, the asymmetric coordination of (Se4+O3)2– (trigonal pyramid) may also give rise to noncentrosymmetric structures with interesting physical properties, such as nonlinear optical second-harmonic generation, piezoelectric, ferroelectric and pyroelectric properties (Porter et al., Reference Porter, Ok, Bhuvanesh and Halasyamani2001; Ok et al., Reference Ok, Bhuvanesh and Halasyamani2001; Ok and Halasyamani, Reference Ok and Halasyamani2002; Kong et al., Reference Kong, Huang, Sun, Mao and Cheng2006; Kim et al., Reference Kim, Yeon and Halasyamani2009, Reference Kim, Kim, Chang, Halasyamani and Ok2010). Conceivably, introduction of other cations with lone-pair electrons into selenite materials (such as Tl+, Sn2+, Pb2+, Sb3+ and Bi3+) will offer more new phases from which additional functionalities may arise (Ok et al., Reference Ok, Bhuvanesh and Halasyamani2001; Porter et al., Reference Porter, Ok, Bhuvanesh and Halasyamani2001; Dityatyev et al. Reference Dityatyev, Smidt, Stefanovich, Lightfoot, Dolgikh and Opperman2004; Krivovichev et al., Reference Krivovichev, Avdontseva and Burns2004; Kim et al. Reference Kim, Yeon and Halasyamani2009; Zhang et al., Reference Zhang, Hu, Li, Jiang and Jiang-Gao Mao2012). On the other hand, because both Se4+ and X - (X = Cl, Br and I) can act as ‘chemical scissors’ (Johnsson et al., Reference Johnsson, Törnroos, Mila and Millet2000, Reference Johnsson, Törnroos, Lemmens and Millet2003; Millet et al., Reference Millet, Johnsson, Pashchenko, Ksari, Stepanov and Mila2001), considerable effort has also been made to incorporate X anions into selenite materials to obtain low dimensional structures, which has resulted in a number of compounds with fascinating magnetic properties (e.g. Becker et al., Reference Becker, Johnsson, Kremer, Klauss and Lemmens2006, Reference Becker, Prester, Berger, Lin, Johnsson, Drobac and Zivkovic2007; Jiang and Mao, Reference Jiang and Mao2006; Zhang et al., Reference Zhang, Johnsson, Berger, Kremer, Wulferding and Lemmens2009, Reference Zhang, Berger, Kremer, Wulferding, Lemmens and Johnsson2010, Reference Zhang, Hu, Li, Jiang and Jiang-Gao Mao2012). Thus far, at least 10 different lead halide selenite phases have been synthesised and structurally characterised, including Pb3(SeO3)(SeO2OH)Cl3 (Porter et al., Reference Porter, Ok, Bhuvanesh and Halasyamani2001), Pb3(SeO3)2Cl2, Pb3(SeO3)2Br2, Pb3(SeO3)2I2, Pb2Cd3(SeO3)4I2(H2O) (Porter and Halasyamani, Reference Porter and Halasyamani2001; Berdonosov et al. Reference Berdonosov, Olenev and Dolgikh2012; Zhang et al., Reference Zhang, Hu, Li, Jiang and Jiang-Gao Mao2012), (Pb2Cu2+9O4)(SeO3)4(Cu+Cl2)Cl5, (PbCu2+5O2)(SeO3)2(Cu+Cl2)Cl3, and (PbxCu2+(6−x)O2)(SeO3)2(Cu+Cl2)K(1−x)Cl(4−x) (x = 0.20) (Kovrugin et al., Reference Kovrugin, Colmont, Siidra, Mentré, Al-Shuray, Gurzhiy and Krivovichev2015), (Cu2+Pb6(SeO3)4Br6, Cu2+Pb2(SeO3)2Br2, Cu2+3Pb2.4(SeO3)5Br0.8, Cu2+2Pb(SeO3)2Br2, Cu2+4Pb(SeO3)4Br2, [Cu2+9Pb2O4](Cu+Br2)(SeO3)4Br5, [Cu2+7PbO3](Cu+Br)0.35(SeO3)3Br4, [Cu2+8Pb2O4](Cu+Br)1.5(SeO3)4Br4, [Cu2+6Pb3O4](Cu+Pb1.27Br3.54)(SeO3)4Br2) (Siidra et al., Reference Siidra, Kozin, Depmeier, Kayukov and Kovrugin2018), Pb2Cd(SeO3)2X 2 (Gong et al. Reference Gong, Hu, Ma, Mao and Kong2019), Pb3(SeO3)(HSeO3)Br3, Pb3(SeO3)(OH)Br3 and CdPb8(SeO3)4Cl4Br6 (Shang and Halasyamani, Reference Shang and Halasyamani2020). In all these compounds, Se4+ only forms bonds with O atoms, whereas Pb2+ can form bonds with both X and O atoms. This paper describes the physical and chemical properties of guangyuanite, and its crystal structure determined from single-crystal X-ray diffraction data.

Sample description and experimental methods

Occurrence, physical and chemical properties, and Raman spectra

Guangyuanite was found on a specimen (Fig. 1) collected from the El Dragón mine (19°49’15’’S, 65°55’0’’W), Antonio Quijarro Province, Potosí Department, Bolivia. Associated minerals are Co-bearing krut'aite–penroseite, chalcomenite, schmiederite, olsacherite, phosgenite, anglesite, cerussite and franksousaite. Detailed descriptions on the geology and mineralogy of the El Dragón mine were given by Grundmann et al. (Reference Grundmann, Lehrberger and Schnorrer-Köhler1990, Reference Grundmann, Lehrberger and Schnorrer-Köhler2007) and Grundmann and Förster (Reference Grundmann and Förster2017). This is an epithermal deposit consisting of a single selenide vein hosted by sandstones and shales. The major ore mineral is krut'aite, CuSe2, varying in composition to penroseite, NiSe2. Later solutions rich in Bi, Pb and Hg resulted in the crystallisation of minerals such as clausthalite, petrovicite, watkinsonite and the recently described minerals eldragónite, Cu6BiSe4(Se2) (Paar et al., Reference Paar, Cooper, Moëlo, Stanley, Putz, Topa, Roberts, Stirling, Raith and Rowe2012), grundmannite, CuBiSe2 (Förster et al., Reference Förster, Bindi and Stanley2016), hansblockite, (Cu,Hg)(Bi,Pb)Se2 (Förster et al., Reference Förster, Bindi, Stanley and Grundmann2017), cerromojonite, CuPbBiSe3 (Förster et al., Reference Förster, Bindi, Grundmann and Stanley2018) and nickeltyrrellite, CuNi2Se4 (Förster et al., Reference Förster, Ma, Grundmann, Bindi and Stanley2019). Oxidation produced a wide range of secondary Se-bearing minerals, such as favreauite, PbBiCu6O4(SeO3)4(OH)⋅H2O (Mills et al., Reference Mills, Kampf, Housley, Christy, Thorne, Chen and Steele2014), alfredopetrovite, Al2(Se4+O3)3⋅6H2O (Kampf et al., Reference Kampf, Mills, Nash, Thorne and Favreau2016b), franksousaite, PbCu(Se6+O4)(OH)2 (Yang et al., Reference Yang and McGlasson2022), bernardevansite, Al2(Se4+O3)3⋅6H2O (Yang et al., Reference Yang, Gu, Jenkins, Gibbs and Downs2023b), petermegawite, Al6(Se4+O3)3[SiO3(OH)](OH)9⋅10H2O (Yang et al., Reference Yang, Gu, Jenkins, Gibbs, McGlasson and Scott2023c) and the new mineral guangyuanite, described herein.

Figure 1. The specimen on which the new mineral guangyuanite, indicated by the blue arrow, was found. Specimen R210013.

Guangyuanite occurs as equant brown-yellowish crystals (Fig. 2) in a vug, where only two crystals were found. The matrix consists of Co-bearing krut'aite–penroseite. Individual crystals of guangyuanite are up to 0.40 × 0.30 × 0.30 mm. Guangyuanite is pale yellow–brown in transmitted light, transparent with white streak and vitreous lustre. It is brittle and has a Mohs hardness of ~3. No cleavage was observed. The density could not be measured because it is greater than available high-density liquids and there is insufficient material for the direct measurement. The calculated density is 6.73 g/cm3 on the basis of the empirical chemical formula and unit cell volume from single-crystal X-ray diffraction data. No optical data were measured because the indices of refraction are too high for measurement with available index liquids. The calculated average index of refraction is 2.04 for the empirical formula based on the Gladstone-Dale relationship (Mandarino, Reference Mandarino1981). Guangyuanite is insoluble in water and hydrochloric acid.

Figure 2. A microscopic view of two yellow-brown guangyuanite crystals in a vug, specimen R210013.

The chemical composition was determined using a Shimadzu-1720 electron microprobe (WDS mode, 15 kV, 10 nA, and a beam diameter of 2 μm). The standards used for the probe analysis are given in Table 2, along with the determined compositions (6 analysis points). The resultant chemical formula, calculated on the basis of 7 (O,Cl) atoms per formula unit (from the structure determination), is Pb3.02Cl3(Se4+0.99O3)(OH), which can be simplified to Pb3Cl3(Se4+O3)(OH). The ideal formula requires (wt.%) PbO 76.80, SeO2 12.73, H2O 1.03, Cl 12.20, O ≡ Cl –2.76, total 100 wt.%.

Table 2. Chemical data (in wt.%) for guangyuanite.

The Raman spectrum of guangyuanite (Fig. 3) was collected on a randomly oriented crystal with a Thermo Almega microRaman system, using a solid-state laser with a wavelength of 532 nm at 50% of 150 mW power and a thermoelectric cooled CCD detector. The laser is partially polarised with 4 cm–1 resolution and a spot size of 1 μm.

Figure 3. Raman spectra of guangyuanite (R210013) and orlandiite (R100122).

X-ray crystallography

Both the powder and single-crystal X-ray diffraction data for guangyuanite were collected on a Rigaku Xtalab Synergy D/S 4-circle diffractometer. Powder X-ray diffraction data were collected with CuKα radiation in the Gandolfi powder mode at 50 kV and 1 mA (Table 3) and the unit-cell parameters were refined using the program by Holland and Redfern (Reference Holland and Redfern1997): a = 10.9920(6), b = 10.6387(7), c = 7.7863(5) Å, and V = 910.55(6) Å3.

Table 3. Powder X-ray diffraction data (d in Å, I in %) for guangyuanite.

Note: The strongest lines are given in bold.

Single-crystal X-ray diffraction data of guangyuanite were collected with MoKα radiation from a 0.05 × 0.05 × 0.04 mm fragment. The systematic absences of reflections suggest possible space group Pn21a or Pnma. The structure was solved and refined using SHELX2019 (Sheldrick, Reference Sheldrick2015a, Reference Sheldrick2015b) based on space group Pnma, because it produced better refinement statistics in terms of bond lengths and angles, atomic displacement parameters, and R factors. The H atom was located through difference-Fourier syntheses. The positions of all atoms were refined with anisotropic displacement parameters, except for the H atom, which was refined with the U iso set to 1.5 times that of O3 on which it rides. The refinement statistics are given in Table 4. Final atomic coordinates and displacement parameters are given in Tables 5 and 6, respectively. Selected bond lengths are presented in Table 7. The bond valences were calculated using the parameters given by Brown (Reference Brown2009) (Table 8). The crystallographic information file has been deposited with the Principal Editor of Mineralogical Magazine and is available as Supplementary material (see below).

Table 4. Crystallographic data and refinement statistics for guangyuanite and orlandiite.

Table 5. Fractional atomic coordinates and equivalent/isotropic displacement parameters (Å2) for guangyuanite.

Table 6. Atomic displacement parameters (Å2) for guangyuanite.

Table 7. Selected bond distances (Å) and angles (°) for guangyuanite and the Br-analogue.

Note: X = Cl and Br for guangyuanite and the Br-analogue, respectively. Data for the Br-analogue were taken from Shang and Halasyamani (Reference Shang and Halasyamani2020)

Table 8. Bond-valence sums for guangyuanite.

Note: superscripts indicate the number of equivalent bonds for the respective sum arrowed.

Crystal structure description and discussion

Guangyuanite is isotypic with synthetic Pb3Br3(Se4+O3)(OH) (Shang and Halasyamani, Reference Shang and Halasyamani2020). Its structure contains two symmetrically distinct Pb (Pb1 and Pb2), two Cl (Cl1 an Cl2), one Se, one H and three O (O1, O2 and O3) atoms, among which O3 is hydroxyl (OH) (Table 8) and forms the hydrogen bond with O2 (Table 7). The Pb1 cation is in a polyhedron coordinated by 4O and 4Cl atoms (Fig. 4a), whereas the Pb2 cation is only bonded by six anions (3O + 3Cl) (Fig. 4b), forming a marked one-sided coordination typical of Pb2+ with a stereochemically-active 6s2 lone-electron pair. The Se4+ cation is bonded to three O atoms, giving rise to the typical [Se4+O3] trigonal pyramid.

Figure 4. Atomic coordinations in guangyuanite: (a) for [Pb1O4Cl4] polyhedron and (b) for [Pb2O3Cl3] and [Se4+O3] groups.

The crystal structure of guangyuanite can be described as consisting of layers of edge-sharing [Pb1O4Cl4] polyhedra parallel to (100) (Fig. 5). These layers are linked together by sharing polyhedral corners (Cl atoms), as well as [Pb2O3Cl3] and [Se4+O3] groups (Fig. 6). The [PbO4Cl4] polyhedra are apparently a basic structural unit in many lead oxychlorides, as observed in nadorite, PbSbO2Cl (Giuseppetti and Tadini, Reference Giuseppetti and Tadini1973), perite, PbBiO2Cl (Gillberg, Reference Gillberg1960), diaboleite, CuPb2Cl2(OH)4 (Cooper and Hawthorne, Reference Cooper and Hawthorne1995), hematophanite Pb4Fe3+3O8(Cl,OH), (Rouse, Reference Rouse1973) and chloroxiphite Pb3CuO2Cl2(OH)2 (Finney et al., Reference Finney, Graeber, Rosenzweig and Hamilton1977; Siidra et al., Reference Siidra, Krivovichev, Turner and Rumsey2008).

Figure 5. A layer of edge-sharing [Pb1O4Cl4] polyhedra (dark grey) in guangyuanite parallel to (100). Light grey, aqua, red, yellow, and green spheres represent Pb2, Cl, O, Se and H atoms, respectively. The unit cell is outlined. Drawn using XtalDraw software (Downs and Hall-Wallace, Reference Downs and Hall-Wallace2003).

Figure 6. Crystal structure of guangyuanite, showing the stacking of layers of edge-sharing [Pb1O4Cl4] polyhedra (dark grey) along the a-axis. The legends are the same as in Fig. 5.

According to Raman or IR spectroscopic studies on hydrous materials containing (SeO3)2– (e.g. Wickleder et al., Reference Wickleder, Buchner, Wickleder, Sheik, Brunklaus and Eckert2004; Frost et al., Reference Frost, Weier, Reddy and Cejka2006; Frost and Keeffe, Reference Frost and Keeffe2008; Djemel et al., Reference Djemel, Abdelhedi, Ktari and Dammak2013; Kasatkin et al., Reference Kasatkin, Plášil, Marty, Agakhanov, Belakovskiy and Lykova2014; Mills et al., Reference Mills, Kampf, Housley, Christy, Thorne, Chen and Steele2014; Kampf et al., Reference Kampf, Mills and Nash2016a; Shang and Halasyamani, Reference Shang and Halasyamani2020), we made the following tentative assignments of major Raman bands for guangyuanite. The broad weak bands between 2850 and 3300 cm–1 (centred at 3130 cm–1) are due to the O–H stretching modes in OH groups. The bands between 665 and 1000 cm–1 are ascribable to the Se4+–O stretching vibrations within the Se4+O3 groups, whereas those from 320 to 570 cm–1 originate from the O–Se4+–O bending modes. The bands below 320 cm–1 are associated mainly with the rotational and translational modes of Se4+O3 groups, as well as the Pb–O and Pb–Cl interactions and lattice vibrational modes.

The calculated bond-valence sums for guangyuanite (Table 8) indicate that O3 is the OH group, which forms a hydrogen bond with O2, with the O3···O2 distance of 2.707 Å (Table 7). According to the correlation between νO–H and O—H···O distances for minerals (Libowitzky, Reference Libowitzky1999), the Raman band centred at 3130 cm–1 corresponds well with the O···O distances between 2.70 and 2.80 Å. In comparison, the O–H stretching band is centred at 3201 cm–1 for isostructural Pb3Br3(Se4+O3)(OH) (Shang and Halasyamani, Reference Shang and Halasyamani2020), which has an O—H⋅⋅⋅O distance of 2.842 Å (Table 7). Because of similarities in both chemistry and structure between guangyuanite and orlandiite, Pb3Cl4(Se4+O3)⋅H2O (Table 4), the Raman spectrum of orlandiite from the RRUFF Project (http://rruff.info/R100122) is also plotted in Fig. 3 for comparison. Evidently, the spectra of two minerals are very alike below 1000 cm–1.

Guangyuanite is one of six lead selenite chloride minerals documented thus far (Table 1), after allochalcoselite Cu1+Cu2+5PbO2(SeO3)2Cl5, orlandiite Pb3Cl4(Se4+O3)⋅H2O, prewittite KPb1.5ZnCu6O2(SeO3)2Cl10, sarrabusite Pb5CuCl4(SeO3)4 and wangkuirenite Pb3Cl2(Se4+O3)2. Chemically, guangyuanite is very similar to orlandiite, the only hydrated mineral in this group. Interestingly, Porter et al. (Reference Porter, Ok, Bhuvanesh and Halasyamani2001) synthesised two lead selenite chlorides: Pb3Cl3(SeO3)(SeO2OH) and Pb3Cl2(SeO3)2, both of which are pseudo-layered, consisting of sheets of lead oxychloride polyhedra linked to (Se4+O3)2–. The latter has been discovered recently in Nature as wangkuirenite (Yang et al., Reference Yang, Gu, Gibbs and Downs2023a), whereas the former has a chemical formula similar to that of guangyuanite. In fact, guangyuanite may be obtained from this compound by removing the Se4+O2 molecule. As both Pb3Cl3(SeO3)(SeO2OH) and Pb3Cl2(SeO3)2 (wangkuirenite) can be readily synthesised using a low-temperature (160°C) aqueous method (Porter et al., Reference Porter, Ok, Bhuvanesh and Halasyamani2001), the former compound may be found in Nature as well someday.

Acknowledgements

We are grateful for the constructive comments by Dr. Luca Bindi, Dr. Peter Leverett, and an anonymous reviewer. This study was funded by the Feinglos family and Mr. Michael M. Scott.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1180/mgm.2023.93.

Competing interests

The authors declare none.

Footnotes

Associate Editor: David Hibbs

References

Becker, R., Johnsson, M., Kremer, R.K., Klauss, H.H. and Lemmens, P. (2006) Crystal structure and magnetic properties of FeTe2O5X (X= Cl, Br): A frustrated spin cluster compound with a new Te(IV) coordination polyhedron. Journal of the American Chemical Society, 128, 1546915475.CrossRefGoogle Scholar
Becker, R., Prester, M., Berger, H., Lin, P.H., Johnsson, M., Drobac, D. and Zivkovic, I. (2007) Crystal structure and magnetic properties of two new cobalt selenite halides: Co5(SeO3)4X2 (X= Cl, Br). Journal of Solid State Chemistry, 180, 10511059.CrossRefGoogle Scholar
Berdonosov, P.S., Stefanovitch, S.Y. and Dolgikh, V.A. (2000) A new bismuth–selenium oxychloride, BiSeO3Cl: crystal structure and dielectric and nonlinear optical properties. Journal of Solid State Chemistry, 149, 236241.CrossRefGoogle Scholar
Berdonosov, P.S., Olenev, A.V. and Dolgikh, V.A. (2012) Lead (II) selenite halides Pb3(SeO3)2X 2 (X = Br, I): Synthesis and crystal structure. Crystallography Reports, 57, 200204.CrossRefGoogle Scholar
Brown, I.D. (2009) Recent developments in the methods and applications of the bond valence model. Chemical Reviews, 109, 68586919.CrossRefGoogle Scholar
Cooper, M.A. and Hawthorne, F.C. (1995) Diaboleite, Pb2Cu(OH)4Cl2, a defect perovskite structure with stereoactive lone-pair behavior of Pb2+. The Canadian Mineralogist, 33, 11251129.Google Scholar
Demartin, F., Gramaccioli, C.M. and Pilati, T. (2003) The crystal structure of orlandiite, Pb3Cl4(SeO3)⋅H2O, a complex case of twinning and disorder. The Canadian Mineralogist, 41, 11471153.CrossRefGoogle Scholar
Dityatyev, O.A., Smidt, P., Stefanovich, S.Y., Lightfoot, P., Dolgikh, V.A. and Opperman, H. (2004) Phase equilibria in the Bi2TeO5–Bi2SeO5 system and a high temperature neutron powder diffraction study of Bi2SeO5. Solid state sciences, 6, 915922.CrossRefGoogle Scholar
Djemel, M., Abdelhedi, M., Ktari, L. and Dammak, M. (2013) X-ray diffraction, Raman study and electrical properties of the new mixed compound Rb1.7K0.3(SO4)0.88(SeO4)0.12Te(OH)6. Journal of Molecular Structure, 1047, 1521.CrossRefGoogle Scholar
Downs, R.T. and Hall-Wallace, M. (2003) The American mineralogist crystal structure database. American Mineralogist, 88, 247250.Google Scholar
Finney, J.J., Graeber, E.J., Rosenzweig, A. and Hamilton, R.D. (1977) The structure of chloroxiphite, Pb3CuO2(OH)2Cl2. Mineralogical Magazine, 41, 357361.CrossRefGoogle Scholar
Förster, H.-J., Bindi, L. and Stanley, C.J. (2016) Grundmannite, CuBiSe2, the Se-analogue of emplectite, a new mineral from the El Dragón mine, Potosí, Bolivia. European Journal of Mineralogy, 28, 467477.CrossRefGoogle Scholar
Förster, H.-J., Bindi, L., Stanley, C.J. and Grundmann, G. (2017) Hansblockite,(Cu,Hg)(Bi,Pb)Se2, the monoclinic polymorph of grundmannite: a new mineral from the Se mineralization at El Dragón (Bolivia). Mineralogical Magazine, 81, 229240.CrossRefGoogle Scholar
Förster, H.-J., Bindi, L., Grundmann, G. and Stanley, C.J. (2018) Cerromojonite, CuPbBiSe3, from El Dragόn (Bolivia): A new member of the bournonite group. Minerals, 8, 420.CrossRefGoogle Scholar
Förster, H.-J., Ma, C., Grundmann, G., Bindi, L. and Stanley, C.J. (2019) Nickeltyrrellite, CuNi2Se4, a New Member of the Spinel Supergroup from El Dragón, Bolivia. The Canadian Mineralogist, 57, 637646.CrossRefGoogle Scholar
Frost, R.L. and Keeffe, E.C. (2008) Raman spectroscopic study of the schmiederite Pb2Cu2[(OH)4|SeO3|SeO4]. Journal of Raman Spectroscopy, 39, 1408–1402.CrossRefGoogle Scholar
Frost, R.L., Weier, M.L., Reddy, B.J. and Cejka, J. (2006) A Raman spectroscopic study of the uranyl selenite mineral haysenite. Journal of Raman Spectroscopy, 37, 816821.CrossRefGoogle Scholar
Gemmi, M., Campostrini, I., Demartin, F., Gorelik, T.E. and Gramaccioli, C.M. (2012) Structure of the new mineral sarrabusite, Pb5CuCl4(SeO3)4, solved by manual electron-diffraction tomography. Acta Crystallographica, B68, 1523.CrossRefGoogle Scholar
Gillberg, M. (1960) Perite, a new oxyhalide mineral from Långban, Sweden. Arkiv för Mineralogi och Geologi, 2, 565570.Google Scholar
Giuseppetti, G. and Tadini, C. (1973) Riesame della struttura cristallina della nadorite: PbSbO2Cl. Periodico di Mineralogia, 42, 335345.Google Scholar
Gong, Y.P., Hu, C.L., Ma, Y.X., Mao, J.G. and Kong, F. (2019) Pb2Cd(SeO3)2X2 (X = Cl and Br): two halogenated selenites with phase matchable second harmonic generation. Inorganic Chemistry Frontiers, 6, 31333139.CrossRefGoogle Scholar
Grundmann, G. and Förster, H.-J. (2017) Origin of the El Dragón Selenium Mineralization, Quijarro Province, Potosí, Bolivia. Minerals, 7, 168.CrossRefGoogle Scholar
Grundmann, G., Lehrberger, G. and Schnorrer-Köhler, G. (1990) The El Dragón mine, Potosí, Bolivia. Mineralogical Record, 21, 133150.Google Scholar
Grundmann, G., Lehrberger, G. and Schnorrer-Köhler, G. (2007) The “El Dragón Mine”, Porco, Potosí, Bolivia – Selenium minerals. Mineral UP, 1, 1625.Google Scholar
Holland, T.J.B. and Redfern, S.A.T. (1997) Unit cell refinement from powder diffraction data: the use of regression diagnostics. Mineralogical Magazine, 61, 6577.CrossRefGoogle Scholar
Jiang, H.L. and Mao, J.G. (2006) New members in the Nin+1(QO3)nX2 family: unusual 3D network based on Ni4ClO3 cubane-like clusters in Ni7(TeO3)6Cl2. Inorganic chemistry, 45, 75937599.CrossRefGoogle Scholar
Johnsson, M., Törnroos, K.W., Mila, F. and Millet, P. (2000) Tetrahedral clusters of copper(II): crystal structures and magnetic properties of Cu2Te2O5X2 (X= Cl, Br). Chemistry of materials, 12, 28532857.CrossRefGoogle Scholar
Johnsson, M., Törnroos, K.W., Lemmens, P. and Millet, P. (2003) Crystal structure and magnetic properties of a new two-dimensional S= 1 quantum spin system Ni5(TeO3)4X2 (X= Cl, Br). Chemistry of materials, 15, 6873.CrossRefGoogle Scholar
Kampf, A.R., Mills, S.J. and Nash, B.P. (2016a) Pauladamsite,Cu4(SeO3)(SO4)(OH)4⋅2H2O, a new mineral from the Santa Rosa mine, Darwin district, California, USA. Mineralogical Magazine, 80, 949958.CrossRefGoogle Scholar
Kampf, A.R., Mills, S.J., Nash, B.P., Thorne, B. and Favreau, G. (2016b) Alfredopetrovite, a new selenite mineral from the El Dragón mine, Bolivia. European Journal of Mineralogy, 28, 479484.CrossRefGoogle Scholar
Kasatkin, A.V., Plášil, J., Marty, J., Agakhanov, A.A., Belakovskiy, D.I. and Lykova, I.S. (2014) Nestolaite, CaSeO3⋅H2O, a new mineral from the Little Eva mine, Grand County, Utah, USA. Mineralogical Magazine, 78, 497505.CrossRefGoogle Scholar
Kim, S.H., Yeon, J. and Halasyamani, P.S. (2009) Noncentrosymmetric polar oxide material, Pb3SeO5: synthesis, characterization, electronic structure calculations, and structure−property relationships. Chemistry of Materials, 21, 53355342.CrossRefGoogle Scholar
Kim, M.K., Kim, S.H., Chang, H.Y., Halasyamani, P.S. and Ok, K.M. (2010) New noncentrosymmetric tellurite phosphate material: synthesis, characterization, and calculations of Te2O(PO4)2. Inorganic chemistry, 49, 70287034.CrossRefGoogle ScholarPubMed
Kong, F., Huang, S.P., Sun, Z.M., Mao, J.G. and Cheng, W.D. (2006) Se2(B2O7): a new type of second-order NLO material. Journal of the American Chemical Society, 128, 77507751.CrossRefGoogle ScholarPubMed
Kovrugin, V.M., Colmont, M., Siidra, O.I., Mentré, O., Al-Shuray, A., Gurzhiy, V.V. and Krivovichev, S.V. (2015) Oxocentered Cu (ii) lead selenite honeycomb lattices hosting Cu (i) Cl2 groups obtained by chemical vapor transport reactions. Chemical Communications, 51, 95639566.CrossRefGoogle Scholar
Krivovichev, S.V., Avdontseva, E.Y. and Burns, P.C. (2004) Synthesis and crystal structure of Pb3O2(SeO3). Zeitschrift für anorganische und allgemeine Chemie, 630, 558562.CrossRefGoogle Scholar
Lafuente, B., Downs, R.T., Yang, H. and Stone, N. (2015) The power of databases: the RRUFF project. Pp. 130 in: Highlights in Mineralogical Crystallography (Armbruster, T. and Danisi, R.M., editors). W. De Gruyter, Berlin, Germany.Google Scholar
Libowitzky, E. (1999) Correlation of O–H stretching frequencies and O–H⋅⋅⋅O hydrogen bond lengths in minerals. Monatshefte für Chemie, 130, 10471059.CrossRefGoogle Scholar
Mandarino, J.A. (1981) The Gladstone–Dale relationship. IV. The compatibility concept and its application. The Canadian Mineralogist, 19, 441450.Google Scholar
Millet, P., Johnsson, M., Pashchenko, V., Ksari, Y., Stepanov, A. and Mila, F. (2001) New copper (II)–lone electron pair elements–oxyhalides compounds: syntheses, crystal structures, and magnetic properties. Solid State Ionics, 141, 559565.CrossRefGoogle Scholar
Mills, S.J., Kampf, A.R., Housley, R.M., Christy, A.G., Thorne, B., Chen, Y.-S. and Steele, I.M. (2014) Favreauite, a new selenite mineral from the El Dragón mine, Bolivia. European Journal of Mineralogy, 26, 771781.CrossRefGoogle Scholar
Ok, K.M. and Halasyamani, P.S. (2002) Anionic templating: Synthesis, structure, and characterization of novel three-dimensional mixed-metal oxychlorides Te4M3O15Cl (M= Nb5+ or Ta5+). Inorganic Chemistry, 41, 38053807.CrossRefGoogle ScholarPubMed
Ok, K.M., Bhuvanesh, N.S.P. and Halasyamani, P.S. (2001) Bi2TeO5: synthesis, structure, and powder second harmonic generation properties. Inorganic Chemistry, 40, 19781980.CrossRefGoogle ScholarPubMed
Paar, W.H., Cooper, M.A., Moëlo, Y., Stanley, C.J., Putz, H., Topa, D., Roberts, A.C., Stirling, J., Raith, J.G. and Rowe, R. (2012) Eldragónite, Cu6BiSe4(Se2), A new mineral species from the El Dragón Mine, Potosí, Bolivia, and its crystal structure. The Canadian Mineralogist, 50, 281294.CrossRefGoogle Scholar
Porter, Y. and Halasyamani, P.S. (2001) A low temperature method for the synthesis of new lead selenite chlorides: Pb3(SeO3)(SeO2OH)Cl3 and Pb3(SeO3)2Cl2. Inorganic Chemistry, 40, 26402641.CrossRefGoogle Scholar
Porter, Y., Ok, K.M., Bhuvanesh, N.S.P. and Halasyamani, P.S. (2001) Synthesis and characterization of Te2SeO7: a powder second-harmonic-generating study of TeO2, Te2SeO7, Te2O5, and TeSeO4. Chemistry of materials, 13, 19101915.CrossRefGoogle Scholar
Rouse, R.C. (1973) Hematophanite, a derivative of the perovskite structure. Mineralogical Magazine, 39, 4953.CrossRefGoogle Scholar
Shang, M. and Halasyamani, P.S. (2020) Mixed lone-pair and mixed anion compounds: Pb3(SeO3)(HSeO3)Br3, Pb3(SeO3)(OH)Br3, CdPb8(SeO3)4Cl4Br6 and RbBi(SeO3)F2. Journal of Solid State Chemistry, 282, 121121.CrossRefGoogle Scholar
Sheldrick, G.M. (2015a) SHELXT – Integrated space-group and crystal structure determination. Acta Crystallographica, A71, 38.Google Scholar
Sheldrick, G.M. (2015b) Crystal structure refinement with SHELX. Acta Crystallographica, C71, 38.Google Scholar
Shuvalov, R.R., Vergasova, L.P., Semenova, T.F., Filatov, S.K., Krivovichev, S.V., Siidra, O.I. and Rudashevsky, N.S. (2013) Prewittite, KPb1.5Cu6Zn(SeO3)2O2Cl10, a new mineral from Tolbachik fumaroles, Kamchatka peninsula, Russia: description and crystal structure. American Mineralogist, 98, 463469.CrossRefGoogle Scholar
Siidra, O.I., Krivovichev, S.V., Turner, R.W. and Rumsey, M.S. (2008) Chloroxiphite Pb3CuO2(OH)2Cl2: structure refinement and description in terms of oxocentred OPb4 tetrahedra. Mineralogical Magazine, 72, 793798.CrossRefGoogle Scholar
Siidra, O., Kozin, M.S., Depmeier, W., Kayukov, R.A. and Kovrugin, V.M. (2018) Copper–lead selenite bromides: a new large family of compounds partly having Cu2+ substructures derivable from kagome nets. Acta Crystallographica, B74, 712724.Google Scholar
Vergasova, L.P., Krivovichev, S.V., Britvin, S.N., Fitatov, S.K., Berns, P.K. and Ananyev, V.V. (2005) Allochalcoselite, Cu+Cu2+5 PbO2(SeO3)2Cl5 – a new mineral from volcanic exhalations (Kamchatka, Russia). Zapiski Rossiiskogo Mineralogicheskogo Obshchetstva, 134, 7074.Google Scholar
Wickleder, M.S. (2002) Inorganic lanthanide compounds with complex anions. Chemical Reviews, 102, 20112088.CrossRefGoogle ScholarPubMed
Wickleder, M.S., Buchner, O., Wickleder, C., Sheik, S.E., Brunklaus, G. and Eckert, H. (2004) Au2(SeO3)2(SeO4): Synthesis and characterization of a new noncentrosymmetric selenite-selenate. Inorganic Chemistry, 43, 58605864.CrossRefGoogle Scholar
Yang, H., McGlasson, J.A., Ronald B. Gibbs R.B. and Downs R.T. (2022) Franksousaite, PbCu(Se6+O4)(OH)2, the Se6+ analogue of linarite, a new mineral from the El Dragón mine, Potosí, Bolivia. Mineralogical Magazine, 86, 792798.CrossRefGoogle Scholar
Yang, H., Gu, X., Gibbs, R.B. and Downs, R.T. (2023a) wangkuirenite, IMA 2023-030. CNMNC Newsletter 74. Mineralogical Magazine, 87, 783787, https://doi.org/10.1180/mgm.2023.54.Google Scholar
Yang, H., Gu, X., Jenkins, R.A., Gibbs, R.B. and Downs, R.T. (2023b) Bernardevansite, Al2(Se4+O3)3⋅6H2O, dimorphous with alfredopetrovite and the Al-analogue of mandarinoite, from the El Dragón mine, Potosí, Bolivia. Mineralogical Magazine, 87, 18.CrossRefGoogle Scholar
Yang, H., Gu, X., Jenkins, R.A., Gibbs, R.B., McGlasson, J.A. and Scott, M.M. (2023c) Petermegawite, Al6(Se4+O3)3[SiO3(OH)](OH)9⋅10H2O, a new Al-bearing selenite mineral, from the El Dragón mine, Potosí, Bolivia. The Canadian Journal of Mineralogy and Petrology, 61, 987998.CrossRefGoogle Scholar
Yang, H., Gu, X., McGlasson, J.A. and Gibbs, R.B. (2023d) Guangyuanite, IMA 2022-124. CNMNC Newsletter 72; Mineralogical Magazine, 87, https://doi.org/10.1180/mgm.2023.21Google Scholar
Zhang, D., Johnsson, M., Berger, H., Kremer, R.K., Wulferding, D. and Lemmens, P. (2009) Separation of the oxide and halide part in the oxohalide Fe3Te3O10Cl due to high Lewis acidity of the cations. Inorganic Chemistry, 48, 65996603.CrossRefGoogle ScholarPubMed
Zhang, D., Berger, H., Kremer, R.K., Wulferding, D., Lemmens, P. and Johnsson, M. (2010) Synthesis, crystal structure, and magnetic properties of the copper selenite chloride Cu5(SeO3)4Cl2. Inorganic chemistry, 49, 96839688.CrossRefGoogle ScholarPubMed
Zhang, S., Hu, C., Li, P., Jiang, H. and Jiang-Gao Mao, J. (2012) Syntheses, crystal structures and properties of new lead(II) or bismuth(III) selenites and tellurite. Dalton Transactions, 41, 95329542.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. List of lead-selenite-chloride minerals.

Figure 1

Figure 1. The specimen on which the new mineral guangyuanite, indicated by the blue arrow, was found. Specimen R210013.

Figure 2

Figure 2. A microscopic view of two yellow-brown guangyuanite crystals in a vug, specimen R210013.

Figure 3

Table 2. Chemical data (in wt.%) for guangyuanite.

Figure 4

Figure 3. Raman spectra of guangyuanite (R210013) and orlandiite (R100122).

Figure 5

Table 3. Powder X-ray diffraction data (d in Å, I in %) for guangyuanite.

Figure 6

Table 4. Crystallographic data and refinement statistics for guangyuanite and orlandiite.

Figure 7

Table 5. Fractional atomic coordinates and equivalent/isotropic displacement parameters (Å2) for guangyuanite.

Figure 8

Table 6. Atomic displacement parameters (Å2) for guangyuanite.

Figure 9

Table 7. Selected bond distances (Å) and angles (°) for guangyuanite and the Br-analogue.

Figure 10

Table 8. Bond-valence sums for guangyuanite.

Figure 11

Figure 4. Atomic coordinations in guangyuanite: (a) for [Pb1O4Cl4] polyhedron and (b) for [Pb2O3Cl3] and [Se4+O3] groups.

Figure 12

Figure 5. A layer of edge-sharing [Pb1O4Cl4] polyhedra (dark grey) in guangyuanite parallel to (100). Light grey, aqua, red, yellow, and green spheres represent Pb2, Cl, O, Se and H atoms, respectively. The unit cell is outlined. Drawn using XtalDraw software (Downs and Hall-Wallace, 2003).

Figure 13

Figure 6. Crystal structure of guangyuanite, showing the stacking of layers of edge-sharing [Pb1O4Cl4] polyhedra (dark grey) along the a-axis. The legends are the same as in Fig. 5.

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