The crystal structure of svabite, Ca5(AsO4)3F, an arsenate member of the apatite supergroup

Biagioni, Cristian; Bosi, Ferdinando; Hålenius, Ulf; Pasero, Marco

doi:10.2138/am-2016-5636

Cited by 4 publications

(1 citation statement)

References 22 publications

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“…As and P, having comparable chemical properties and a tetrahedral geometry, usually form solid solution series minerals (Bajda et al 2011;Biagioni et al 2016).…”

Section: Introductionmentioning

confidence: 99%

The new mineral cuprozheshengite, Pb4CuZn2(AsO4)2(PO4)2(OH)2, from Yunnan, China, with site-selective As-P substitution

Sun,

Grey,

et al. 2024

American Mineralogist

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corner-connected [X1O 4 ] tetrahedra. These two columns are connected by corner-sharing between [ IV BO 4 ] and [X1O 4 ] tetrahedra to form layers parallel to (011).Pb atoms occupy two independent sites between the layers. Cuprozheshengite is named as the copper analogue of zheshengite. Single-crystal X-ray study reveals that As-P ordering separation in X1 and X2 sites and As tends to occupy the X1 site preferentially. The structural geometric parameters and density functional theory (DFT) calculation study of cuprozheshengite provide critical evidence for the occupancy propensity of As benefiting structural stability, which provides a new idea for studying other rare minerals with atoms ordering at different sites. Besides, the structure and stability studies of cuprozheshengite may have implications for local environmental governance. As a stable mineral in the water and elemental cycles after weathering, cuprozheshengite still has the potential to continually crystallize in the local area. By converting waste pollution into a crystalline form, humans can maintain favorable environmental conditions comparable to geological periods on Earth.

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“…As and P, having comparable chemical properties and a tetrahedral geometry, usually form solid solution series minerals (Bajda et al 2011;Biagioni et al 2016).…”

Section: Introductionmentioning

confidence: 99%

The new mineral cuprozheshengite, Pb4CuZn2(AsO4)2(PO4)2(OH)2, from Yunnan, China, with site-selective As-P substitution

Sun,

Grey,

et al. 2024

American Mineralogist

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Hydroxylhedyphane, Ca2Pb3(AsO4)3(OH), a new member of the apatite supergroup from Långban, Sweden

Biagioni

Hålenius

Pasero

et al. 2019

ejm

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The crystal structure of turneaureite, Ca₅(AsO₄)₃Cl, the arsenate analog of chlorapatite, and its relationships with the arsenate apatites johnbaumite and svabite

Biagioni

Bosi

Hålenius

et al. 2017

American Mineralogist

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The crystal structure of turneaureite, ideally Ca5(AsO4)3Cl, was studied using a specimen from the Brattfors mine, Nordmark, VÃ¤rmland, Sweden, by means of single-crystal X-ray diffraction data. The structure was refined to R1= 0.017 on the basis of 716 unique reflections with Fo> 4Ï\u83(Fo) in the P63/m space group, with unit-cell parameters a = 9.9218(3), c = 6.8638(2) Ã\u85, V = 585.16(4) Ã\u853. The chemical composition of the sample, determined by electron-microprobe analysis, is (in wt%; average of 10 spot analyses): SO30.22, P2O50.20, V2O50.01, As2O551.76, SiO20.06, CaO 41.39, MnO 1.89, SrO 0.12, BaO 0.52, PbO 0.10, Na2O 0.02, F 0.32, Cl 2.56, H2Ocalc0.58, O(=F+Cl)-0.71, total 99.04. On the basis of 13 anions per formula unit, the empirical formula corresponds to (Ca4.82Mn0.17Ba0.02Sr0.01)Î£5.02(As2.94P0.02S0.02Si0.01)Î£2.99O12[Cl0.47(OH)0.42F0.11]Î£1.00. Turneaureite is topologically similar to the other members of the apatite supergroup: columns of face-sharing M1 polyhedra running along c are connected through TO4tetrahedra with channels hosting M2 cations and X anions. Owing to its particular chemical composition, the studied turneaureite can be considered as a ternary calcium arsenate apatite; consequently it has several partially filled anion sites within the anion columns. Polarized single-crystal FTIR spectra of the studied sample indicate stronger hydrogen bonding and less diverse short-range atom arrangements around (OH) groups in turneaureite as compared to the related minerals johnbaumite and svabite. An accurate knowledge of the atomic arrangement of this apatite-remediation mineral represents an improvement in our understanding of minerals able to sequester and stabilize heavy metals such as arsenic in polluted areas

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The crystal structure of svabite, Ca₅(AsO₄)₃F, an arsenate member of the apatite supergroup

Cited by 4 publications

References 22 publications

The new mineral cuprozheshengite, Pb4CuZn2(AsO4)2(PO4)2(OH)2, from Yunnan, China, with site-selective As-P substitution

The new mineral cuprozheshengite, Pb4CuZn2(AsO4)2(PO4)2(OH)2, from Yunnan, China, with site-selective As-P substitution

Hydroxylhedyphane, Ca2Pb3(AsO4)3(OH), a new member of the apatite supergroup from Långban, Sweden

The crystal structure of turneaureite, Ca₅(AsO₄)₃Cl, the arsenate analog of chlorapatite, and its relationships with the arsenate apatites johnbaumite and svabite

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The crystal structure of svabite, Ca5(AsO4)3F, an arsenate member of the apatite supergroup

Cited by 4 publications

References 22 publications

The new mineral cuprozheshengite, Pb4CuZn2(AsO4)2(PO4)2(OH)2, from Yunnan, China, with site-selective As-P substitution

The new mineral cuprozheshengite, Pb4CuZn2(AsO4)2(PO4)2(OH)2, from Yunnan, China, with site-selective As-P substitution

Hydroxylhedyphane, Ca2Pb3(AsO4)3(OH), a new member of the apatite supergroup from Långban, Sweden

The crystal structure of turneaureite, Ca5(AsO4)3Cl, the arsenate analog of chlorapatite, and its relationships with the arsenate apatites johnbaumite and svabite

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The crystal structure of svabite, Ca₅(AsO₄)₃F, an arsenate member of the apatite supergroup

The crystal structure of turneaureite, Ca₅(AsO₄)₃Cl, the arsenate analog of chlorapatite, and its relationships with the arsenate apatites johnbaumite and svabite