Synthesis and crystal structure of a new alluaudite-like iron phosphate Na2CaMnFe(PO4)3

Jebli, S.; Badri, A.; Ben Amara, M.

doi:10.1107/S2056989016017771

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Volume 72| Part 12| December 2016| Pages 1806-1808

https://doi.org/10.1107/S2056989016017771

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Synthesis and crystal structure of a new alluaudite-like iron phosphate Na₂CaMnFe(PO₄)₃

Semeh Jebli,^a ^* Abdessalem Badri ^a and Mongi Ben Amara ^a

^aUnité de Recherche, Matériaux Inorganiques, Faculté des Sciences, Université de Monastir, 5019, Monastir, Tunisia
^*Correspondence e-mail: seme7jebli@gmail.com

Edited by I. D. Brown, McMaster University, Canada (Received 30 August 2016; accepted 7 November 2016; online 15 November 2016)

A new iron phosphate, disodium calcium manganese(II) iron(III) tris(phosphate), Na₂CaMnFe(PO₄)₃, has been synthesized as single crystals by the flux technique. This compound crystallizes in the monoclinic space group C2/c. The structure belongs to the alluaudite structural type and thus, it obeys the X(2)X(1)M(1)M(2)₂(PO₄)₃ general formula. Both the X(2) and X(1) sites are fully occupied by sodium, while M(1) is occupied by calcium and M(2) exhibits a statistical distribution of iron and manganese.

Keywords: XRD; iron phosphate; alluaudite structure; crystal structure.

CCDC reference: 1515407

1. Chemical context

A promising line of research in the materials science field is the creation of materials based on inorganic phosphates, which have considerable potential for use in laser engineering, optics and electronics owing to their non-linear optical, electrical and luminescent properties. In recent years, iron monophosphates have assumed great importance for their promising applications in several fields such as catalysis (Moffat, 1978 ), corrosion inhibition (Meisel et al., 1983 ) and electrochemistry as a positive electrode for lithium ion batteries (Padhi et al., 1997 ; Ravet et al.,2005 ; Trad et al., 2010 ). The physical properties of inorganic materials are related to their structure. A large number of iron phosphates belong to the alluaudite structure type (Yakubovich et al., 1977 ; Corbin et al., 1986 ; Korzenski et al., 1998 ; Hatert et al., 2003 ; Strutynska et al., 2013 ) discovered for the first time from natural minerals by Fisher (1955 ). The term alluaudite refers to a large family of natural or synthetic compounds with the general formula proposed by Moore (1971 ) of X(2)X(1)M(1)M(2)₂(PO₄)₃ with X and M being cationic sites ranked in descending order of size. The M sites are fully occupied while the X sites can be empty or partially occupied. In this paper, we report a structural study of a new composition of alluaudite-like iron phosphate Na₂CaMnFe(PO₄)₃. In this compound the M(1) and M(2) sites are occupied by Ca and (0.5Mn + 0.5Fe), respectively, while the X(1) and X(2) sites are fully occupied by Na atoms.

In iron phosphates adopting the alluaudite-type structure, the M(2) site is often preferentially occupied by iron with oxidation state +III. Consequently, and on basis of the Mössbauer spectroscopy results observed in similar compounds, the presence of Fe^II and Mn^III in the M(2) site was not considered in the Na₂CaMnFe(PO₄)₃ compound. Indeed, in Na₂Mn₂Fe(PO₄)₃ (Hidouri et al., 2011 ), iron and manganese adopt exclusively the oxidation states +III and +II, respectively, whereas in NaMnFe₂(PO₄)₃ (Trad et al., 2010), Mn^III and Fe^II were observed in very low amounts, leading to a Mn/Fe ratio close to 1.

2. Structural commentary

The structure of the title compound consists of infinite chains (Fig. 1) formed by a succession of pairs of M(2)O₆ octahedra linked together by common edges and sharing edges with a strongly distorted M(1)O₈ polyhedron. Connected equivalent chains through the PO₄ tetrahedra lead to the formation of sheets stacked parallel to the ac plane (Fig. 2) and interconnected along the b axis by PO₄ tetrahedra. The resulting three-dimensional anionic framework exhibits two kinds of tunnels parallel to the c axis situated at (1/2, 0, z) and (0, 0, z) (Fig. 3) and occupied by the Na⁺ ions. Fig. 4 shows the displacement ellipsoids of the coordination polyhedra of Ca, Mn/Fe, P1 and P2.

Figure 1
View of a chain showing the distorted octahedral sites M(1) (orange polyhedra) and M(2) (cyan polyhedra).

Figure 2
View showing a sheet made of MO₆ octahedra and PO₄ tetrahedra (light grey).

Figure 3
View of the alluaudite structure in the ab plane. The polyhedra represent a chain of MO₆ octahedra parallel to [101]; Tunnel 1 (light-green atoms) and Tunnel 2 (dark-green atoms).

Figure 4
The environment of atoms (a) Ca, (b) Mn/Fe, (c) P1 and (d) P2.

The M(2)—O distances and the O—M(2)—O angles range from 2.027 (2) to 2.246 (2) Å and from 80.11 (9) to 174.29 (9)°, respectively. This dispersion evidences an important distortion of the M(2)O₆ octahedron due to edge-sharing. The M(1)O₈ polyhedron is also very distorted as indicated by the M(1)—O distances and the O—M(1)—O angles which vary from 2.336 (2) to 2.951 (3) Å and from 54.00 (8) to 161.85 (8)°, respectively. In the P1O₄ and P2O₄ tetrahedra, the P—O distances vary between 1.521 (2) and 1.547 (2) Å. Their mean distances 〈P1—O〉= 1.538 (2) Å and 〈P2—O〉= 1.537 (2) Å are in a good accordance with the value of 1.537 Å calculated by Baur (1974 ) for monophosphate groups.

Assuming sodium–oxygen distances below 3.0, both the Na1 and Na2 sites are surrounded by six oxygen atoms. Their environments approximate strongly distorted octahedra (Fig. 5). Note that in the ideal alluaudite-type structure, both X(2) and X(1) sites are eightfold coordinated, such as for example in Na₂Mn₂Fe(PO₄)₃ and Na₂Cd₂Fe(PO₄)₃ (Hidouri et al., 2011). However, in Na₄CaFe₄(PO₄)₆ (Hidouri et al., 2004 ), the coordination numbers of the X(1) and X(2) sites are eight and six, respectively. The decrease of the X(2) coordination number seems to be related to the presence of calcium (0.5 Ca + 0.5 Na) in the M(1) site. In the title compound, the decrease of the coordination numbers from eight to six for both the X(1) and X(2) sites is probably related to the increase of the calcium content in the M(1) site, which becomes exclusively occupied by calcium.

Figure 5
The environment of cations (a) Na1 and (b) Na2.

3. Synthesis and crystallization

Single crystals of the title compound were obtained in a flux of sodium dimolybdate Na₂Mo₂O₇. A starting mixture of appropriate amounts of Fe(NO₃)₃·9H₂O (3.999 g); Mn(NO₃)₂·6H₂O (2.472 g); CaCO₃ (0.985 g); (NH₄)₂HPO₄ (3.921 g); Na₂CO₃ (1.845 g) and MoO₃ (2.148 g) was dissolved in nitric acid and then dried for 24 h at 353 K. The dry residue was well ground in an agate mortar and was gradually heated up to 873 K in a platinum crucible to evacuate the decomposition products NH₃, CO₂ and H₂O. Then, the obtained product was melted for 1 h at 1073 K and was cooled slowly to 473 K at a rate of 10 K h⁻¹. Finally, hexagonally shaped brown crystals of Na₂CaMnFe(PO₄)₃ were obtained after washing the mixture with boiling water.

4. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1. The refinement was performed on the basis of electrical neutrality and previous work. Application of direct methods revealed the position of the site, labeled M(2), statistically occupied by the Fe³⁺ and Mn²⁺ ions. This distribution was supported by the M(2)—O distances, which range between those of Mn—O and Fe—O observed in similar environments.

Table 1
Experimental details

Crystal data
Chemical formula	Na₂CaMnFe(PO₄)₃
M_r	481.76
Crystal system, space group	Monoclinic, C2/c
Temperature (K)	293
a, b, c (Å)	12.283 (1), 12.736 (1), 6.494 (5)
β (°)	114.76 (3)
V (Å³)	922.5 (7)
Z	4
Radiation type	Mo Kα
μ (mm⁻¹)	4.19
Crystal size (mm)	0.22 × 0.14 × 0.07

Data collection
Diffractometer	Enraf–Nonius TurboCAD-4
Absorption correction	ψ scan (North et al., 1968 )
T_min, T_max	0.514, 0.689
No. of measured, independent and observed [I > 2σ(I)] reflections	1780, 1333, 1139
R_int	0.023
(sin θ/λ)_max (Å⁻¹)	0.702

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.028, 0.081, 1.07
No. of reflections	1333
No. of parameters	97
No. of restraints	2
Δρ_max, Δρ_min (e Å⁻³)	0.63, −0.90
Computer programs: CAD-4 EXPRESS (Enraf–Nonius, 1994 ), XCAD4 (Harms & Wocadlo, 1995 ), SIR92 (Altomare et al., 1993 ), SHELXL2014 (Sheldrick, 2015 ), DIAMOND (Brandenburg, 1999 ) and WinGX (Farrugia, 2012 ).

Supporting information

CCDC reference: 1515407

Crystal structure: contains datablocks global, I. DOI: https://doi.org/10.1107/S2056989016017771/br2263sup1.cif

Structure factors: contains datablock I. DOI: https://doi.org/10.1107/S2056989016017771/br2263Isup2.hkl

checkCIF report

Computing details top

Data collection: CAD-4 EXPRESS (Enraf–Nonius, 1994); cell refinement: CAD-4 EXPRESS (Enraf–Nonius, 1994); data reduction: XCAD4 (Harms & Wocadlo, 1995); program(s) used to solve structure: SIR92 (Altomare et al., 1993); program(s) used to refine structure: SHELXL2014 (Sheldrick, 2015); molecular graphics: DIAMOND (Brandenburg, 1999); software used to prepare material for publication: WinGX (Farrugia, 2012).

Disodium calcium manganese iron tris(phosphate) top

Crystal data top

Na₂CaMnFe(PO₄)₃	F(000) = 936
M_r = 481.76	D_x = 3.469 Mg m⁻³
Monoclinic, C2/c	Mo Kα radiation, λ = 0.71073 Å
a = 12.283 (1) Å	Cell parameters from 25 reflections
b = 12.736 (1) Å	θ = 8.0–14.7°
c = 6.494 (5) Å	µ = 4.19 mm⁻¹
β = 114.76 (3)°	T = 293 K
V = 922.5 (7) Å³	Prism, brown
Z = 4	0.22 × 0.14 × 0.07 mm

Data collection top

Enraf–Nonius TurboCAD-4 diffractometer	R_int = 0.023
Radiation source: fine-focus sealed tube	θ_max = 30.0°, θ_min = 2.4°
non–profiled ω/2τ scans	h = −17→16
Absorption correction: ψ scan (North et al., 1968)	k = −1→17
T_min = 0.514, T_max = 0.689	l = −1→9
1780 measured reflections	2 standard reflections every 60 min
1333 independent reflections	intensity decay: none
1139 reflections with I > 2σ(I)

Refinement top

Refinement on F²	2 restraints
Least-squares matrix: full	w = 1/[σ²(F_o²) + (0.0351P)² + 3.0677P] where P = (F_o² + 2F_c²)/3
R[F² > 2σ(F²)] = 0.028	(Δ/σ)_max < 0.001
wR(F²) = 0.081	Δρ_max = 0.63 e Å⁻³
S = 1.07	Δρ_min = −0.90 e Å⁻³
1333 reflections	Extinction correction: SHELXL2014 (Sheldrick, 2015), Fc^*=kFc[1+0.001xFc²λ³/sin(2θ)]^-1/4
97 parameters	Extinction coefficient: 0.0026 (4)

Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
Na1	0.5000	0.0000	0.0000	0.0223 (4)
Na2	0.0000	0.0217 (2)	0.7500	0.0464 (7)
Ca	0.0000	0.26845 (6)	0.2500	0.01178 (18)
Mn	0.22734 (3)	0.15466 (3)	0.14341 (7)	0.01013 (14)	0.4999 (3)
Fe	0.22734 (3)	0.15466 (3)	0.14341 (7)	0.01013 (14)	0.5001 (2)
P1	0.0000	0.27735 (8)	0.7500	0.0081 (2)
O11	0.05225 (18)	0.20662 (17)	0.9616 (3)	0.0139 (4)
O12	0.0910 (2)	0.35033 (18)	0.7174 (4)	0.0204 (5)
P2	0.23941 (6)	−0.10428 (6)	0.13282 (11)	0.00951 (17)
O21	0.37036 (19)	−0.08841 (17)	0.1794 (4)	0.0160 (4)
O22	0.1756 (2)	0.00101 (19)	0.1190 (4)	0.0228 (5)
O23	0.1718 (2)	−0.16191 (17)	−0.0952 (4)	0.0165 (4)
O24	0.23187 (19)	−0.17266 (18)	0.3233 (4)	0.0164 (4)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
Na1	0.0296 (10)	0.0080 (8)	0.0110 (8)	−0.0041 (7)	−0.0095 (7)	0.0027 (6)
Na2	0.0339 (13)	0.0492 (16)	0.0406 (15)	0.000	0.0004 (11)	0.000
Ca	0.0109 (3)	0.0092 (4)	0.0175 (4)	0.000	0.0082 (3)	0.000
Mn	0.0079 (2)	0.0119 (2)	0.0101 (2)	−0.00091 (14)	0.00324 (16)	−0.00062 (14)
Fe	0.0079 (2)	0.0119 (2)	0.0101 (2)	−0.00091 (14)	0.00324 (16)	−0.00062 (14)
P1	0.0079 (4)	0.0090 (4)	0.0060 (4)	0.000	0.0016 (3)	0.000
O11	0.0132 (9)	0.0180 (10)	0.0082 (8)	−0.0031 (8)	0.0023 (7)	0.0036 (8)
O12	0.0163 (10)	0.0184 (11)	0.0255 (12)	−0.0014 (8)	0.0076 (9)	0.0111 (9)
P2	0.0116 (3)	0.0087 (3)	0.0062 (3)	0.0015 (2)	0.0017 (2)	0.0004 (2)
O21	0.0143 (9)	0.0160 (10)	0.0160 (10)	−0.0034 (8)	0.0049 (8)	−0.0015 (8)
O22	0.0291 (12)	0.0189 (11)	0.0173 (11)	0.0124 (9)	0.0064 (10)	−0.0018 (9)
O23	0.0211 (10)	0.0138 (10)	0.0094 (9)	−0.0034 (8)	0.0012 (8)	−0.0015 (8)
O24	0.0159 (9)	0.0212 (11)	0.0114 (10)	−0.0005 (9)	0.0052 (8)	0.0028 (8)

Geometric parameters (Å, º) top

Na1—O21ⁱ	2.315 (2)	Ca—O11^x	2.355 (3)
Na1—O21ⁱⁱ	2.315 (2)	Ca—O12^vi	2.951 (3)
Na1—O12ⁱⁱⁱ	2.357 (2)	Ca—O12	2.951 (3)
Na1—O12^iv	2.357 (2)	Mn—O12^xv	2.027 (2)
Na1—O21^v	2.591 (2)	Mn—O22	2.043 (3)
Na1—O21	2.591 (2)	Mn—O23^ix	2.080 (3)
Na2—O22^vi	2.477 (3)	Mn—O11^xiv	2.081 (2)
Na2—O22^vii	2.477 (3)	Mn—O24ⁱ	2.115 (3)
Na2—O22^viii	2.645 (3)	Mn—O24^xi	2.246 (2)
Na2—O22^ix	2.645 (3)	P1—O12^x	1.535 (2)
Na2—O11^x	2.667 (3)	P1—O12	1.535 (2)
Na2—O11	2.667 (3)	P1—O11	1.541 (2)
Ca—O21^xi	2.336 (2)	P1—O11^x	1.541 (2)
Ca—O21^xii	2.336 (2)	P2—O21	1.521 (2)
Ca—O23^xiii	2.351 (2)	P2—O22	1.537 (2)
Ca—O23^ix	2.351 (2)	P2—O23	1.546 (2)
Ca—O11^xiv	2.355 (3)	P2—O24	1.547 (2)

O21ⁱ—Na1—O21ⁱⁱ	180.00 (13)	O23^ix—Ca—O11^x	87.80 (8)
O21ⁱ—Na1—O12ⁱⁱⁱ	96.91 (9)	O11^xiv—Ca—O11^x	140.93 (11)
O21ⁱⁱ—Na1—O12ⁱⁱⁱ	83.09 (9)	O21^xi—Ca—O12^vi	81.93 (8)
O21ⁱ—Na1—O12^iv	83.09 (9)	O21^xii—Ca—O12^vi	65.72 (7)
O21ⁱⁱ—Na1—O12^iv	96.91 (9)	O23^xiii—Ca—O12^vi	83.03 (8)
O12ⁱⁱⁱ—Na1—O12^iv	180.00 (13)	O23^ix—Ca—O12^vi	121.96 (7)
O21ⁱ—Na1—O21^v	72.85 (9)	O11^xiv—Ca—O12^vi	54.00 (8)
O21ⁱⁱ—Na1—O21^v	107.15 (9)	O11^x—Ca—O12^vi	145.50 (7)
O12ⁱⁱⁱ—Na1—O21^v	72.01 (9)	O21^xi—Ca—O12	65.72 (7)
O12^iv—Na1—O21^v	107.99 (9)	O21^xii—Ca—O12	81.93 (8)
O21ⁱ—Na1—O21	107.15 (9)	O23^xiii—Ca—O12	121.96 (7)
O21ⁱⁱ—Na1—O21	72.85 (9)	O23^ix—Ca—O12	83.03 (8)
O12ⁱⁱⁱ—Na1—O21	107.99 (9)	O11^xiv—Ca—O12	145.50 (7)
O12^iv—Na1—O21	72.01 (9)	O11^x—Ca—O12	54.00 (8)
O21^v—Na1—O21	180.0	O12^vi—Ca—O12	138.61 (10)
O22^vi—Na2—O22^vii	167.80 (17)	O12^xv—Mn—O22	104.67 (10)
O22^vi—Na2—O22^viii	78.62 (9)	O12^xv—Mn—O23^ix	108.27 (10)
O22^vii—Na2—O22^viii	100.03 (9)	O22—Mn—O23^ix	84.73 (9)
O22^vi—Na2—O22^ix	100.03 (9)	O12^xv—Mn—O11^xiv	161.07 (9)
O22^vii—Na2—O22^ix	78.62 (9)	O22—Mn—O11^xiv	92.66 (9)
O22^viii—Na2—O22^ix	167.47 (16)	O23^ix—Mn—O11^xiv	80.46 (9)
O22^vi—Na2—O11^x	70.80 (8)	O12^xv—Mn—O24ⁱ	87.98 (10)
O22^vii—Na2—O11^x	121.10 (12)	O22—Mn—O24ⁱ	99.38 (10)
O22^viii—Na2—O11^x	102.10 (9)	O23^ix—Mn—O24ⁱ	161.79 (9)
O22^ix—Na2—O11^x	89.04 (9)	O11^xiv—Mn—O24ⁱ	81.62 (9)
O22^vi—Na2—O11	121.10 (12)	O12^xv—Mn—O24^xi	80.11 (9)
O22^vii—Na2—O11	70.80 (8)	O22—Mn—O24^xi	174.29 (9)
O22^viii—Na2—O11	89.04 (9)	O23^ix—Mn—O24^xi	90.82 (8)
O22^ix—Na2—O11	102.10 (9)	O11^xiv—Mn—O24^xi	83.06 (8)
O11^x—Na2—O11	55.90 (11)	O24ⁱ—Mn—O24^xi	83.79 (9)
O21^xi—Ca—O21^xii	77.41 (11)	O12^x—P1—O12	105.48 (19)
O21^xi—Ca—O23^xiii	161.85 (8)	O12^x—P1—O11	106.63 (13)
O21^xii—Ca—O23^xiii	87.17 (8)	O12—P1—O11	114.95 (12)
O21^xi—Ca—O23^ix	87.17 (8)	O12^x—P1—O11^x	114.95 (12)
O21^xii—Ca—O23^ix	161.85 (8)	O12—P1—O11^x	106.63 (13)
O23^xiii—Ca—O23^ix	109.49 (11)	O11—P1—O11^x	108.44 (18)
O21^xi—Ca—O11^xiv	91.53 (8)	O21—P2—O22	111.53 (14)
O21^xii—Ca—O11^xiv	119.68 (8)	O21—P2—O23	110.66 (13)
O23^xiii—Ca—O11^xiv	87.80 (8)	O22—P2—O23	107.57 (13)
O23^ix—Ca—O11^xiv	69.66 (8)	O21—P2—O24	109.17 (13)
O21^xi—Ca—O11^x	119.68 (8)	O22—P2—O24	109.76 (14)
O21^xii—Ca—O11^x	91.53 (8)	O23—P2—O24	108.08 (13)
O23^xiii—Ca—O11^x	69.66 (8)

Symmetry codes: (i) x, −y, z−1/2; (ii) −x+1, y, −z+1/2; (iii) x+1/2, −y+1/2, z−1/2; (iv) −x+1/2, y−1/2, −z+1/2; (v) −x+1, −y, −z; (vi) −x, y, −z+1/2; (vii) x, y, z+1; (viii) −x, −y, −z+1; (ix) x, −y, z+1/2; (x) −x, y, −z+3/2; (xi) −x+1/2, y+1/2, −z+1/2; (xii) x−1/2, y+1/2, z; (xiii) −x, −y, −z; (xiv) x, y, z−1; (xv) −x+1/2, −y+1/2, −z+1.

References

Altomare, A., Cascarano, G., Giacovazzo, C. & Guagliardi, A. (1993). J. Appl. Cryst. 26, 343–350. CrossRef Web of Science IUCr Journals Google Scholar
Baur, W. H. (1974). Acta Cryst. B30, 1195–1215. CrossRef CAS IUCr Journals Web of Science Google Scholar
Brandenburg, K. (1999). DIAMOND. University of Bonn, Germany. Google Scholar
Corbin, D. R., Whitney, J. F., Fultz, W. C., Stucky, G. D., Eddy, M. M. & Cheetham, A. K. (1986). Inorg. Chem. 25, 2279–2280. CrossRef CAS Web of Science Google Scholar
Enraf–Nonius (1994). CAD-4 EXPRESS. Enraf–Nonius, Delft, The Netherlands. Google Scholar
Farrugia, L. J. (2012). J. Appl. Cryst. 45, 849–854. Web of Science CrossRef CAS IUCr Journals Google Scholar
Fisher, D. J. (1955). Am. Mineral. 40, 1100–1109. CAS Google Scholar
Harms, K. & Wocadlo, S. (1995). XCAD4. University of Marburg, Germany. Google Scholar
Hatert, F., Hermann, R. P., Long, G. J., Fransolet, A.-M. & Grandjean, F. (2003). Am. Mineral. 88, 211–222. CrossRef CAS Google Scholar
Hidouri, M., Lajmi, B., Wattiaux, A., Fournés, L., Darriet, J. & Amara, M. B. (2004). J. Solid State Chem. 177, 55–60. Web of Science CrossRef CAS Google Scholar
Hidouri, M., Wattiaux, A., Fournés, L., Darriet, J. & Amara, M. B. (2011). C. R. Chim. 14, 904–910. Web of Science CrossRef CAS Google Scholar
Korzenski, M. B., Schimek, G. L., Kolis, J. W. & Long, G. J. (1998). J. Solid State Chem. 139, 152–160. Web of Science CrossRef CAS Google Scholar
Meisel, W., Guttmann, H. J. & Gütlich, P. (1983). Corros. Sci. 23, 1373–1379. CrossRef CAS Web of Science Google Scholar
Moffat, J. B. (1978). Catal. Rev. 18, 199–258. CrossRef CAS Web of Science Google Scholar
Moore, P. B. (1971). Am. Mineral. 56, 1955–1975. CAS Google Scholar
North, A. C. T., Phillips, D. C. & Mathews, F. S. (1968). Acta Cryst. A24, 351–359. CrossRef IUCr Journals Web of Science Google Scholar
Padhi, A., Nanjundaswamy, K. & Goodenough, J. (1997). J. Electrochem. Soc. 144, 1188–1194. CrossRef CAS Web of Science Google Scholar
Ravet, N., Besner, S., Simoneau, M., Vallée, A., Armand, M. & Magnan, J. F. (2005). US Patent 6,962,666. Google Scholar
Sheldrick, G. M. (2015). Acta Cryst. C71, 3–8. Web of Science CrossRef IUCr Journals Google Scholar
Strutynska, N. Yu., Kovba, Ya. Yu., Zatovsky, I. V., Baumer, V. N., Ogorodnyk, I. V. & Slobodyanik, N. S. (2013). Inorg. Mater. 49, 709–714. Web of Science CrossRef CAS Google Scholar
Trad, K., Carlier, D., Croguennec, L., Wattiaux, A., Lajmi, B., Ben Amara, M. & Delmas, C. (2010). J. Phys. Chem. C, 114, 10034–10044. Web of Science CrossRef CAS Google Scholar
Yakubovich, O. V., Simonov, M. A., Tismenko, Y. K. E. & Belov, N. V. (1977). Dokl. Acad. Nauk SSSR, 236, 1123–1126. CAS Google Scholar

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