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Journal logoCRYSTALLOGRAPHIC
COMMUNICATIONS
ISSN: 2056-9890
Volume 72| Part 2| February 2016| Pages 220-222

Crystal structure of (Na0.70)(Na0.70,Mn0.30)(Fe3+,Fe2+)2Fe2+(VO4)3, a sodium-, iron- and manganese-based vanadate with the alluaudite-type structure

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aLaboratoire de Chimie du Solide Appliquée, Faculté des Sciences, Université Mohammed V de Rabat, Avenue Ibn Battouta, BP 1014, Rabat, Morocco
*Correspondence e-mail: el_benhsina@yahoo.fr

Edited by M. Weil, Vienna University of Technology, Austria (Received 21 December 2015; accepted 15 January 2016; online 23 January 2016)

The title compound, sodium (sodium,manganese) triiron(II,III) tris[vana­date(V)], (Na0.70)(Na0.70,Mn0.30)(Fe3+,Fe2+)2Fe2+(VO4)3, was prepared by solid-state reactions. It crystallizes in an alluaudite-like structure, characterized by a partial cationic disorder. In the structure, four of the 12 sites in the asymmetric unit are located on special positions, three on a twofold rotation axis (Wyckoff position 4e) and one on an inversion centre (4b). Two sites on the twofold rotation axis are entirely filled by Fe2+ and V5+, whereas the third site has a partial occupancy of 70% by Na+. The site on the inversion centre is occupied by Na+ and Mn2+ cations in a 0.7:0.3 ratio. The remaining Fe2+ and Fe3+ atoms are statistically distributed on a general position. The three-dimensional framework of this structure is made up of kinked chains of edge-sharing [FeO6] octa­hedra stacked parallel to [10-1]. These chains are held together by VO4 tetra­hedral groups, forming polyhedral sheets perpendicular to [010]. Within this framework, two types of channels extending along [001] are present. One is occupied by (Na+/Mn2+) while the second is partially occupied by Na+. The mixed site containing (Na+/Mn2+) has an octa­hedral coordination sphere, while the Na+ cations in the second channel are coordinated by eight O atoms.

1. Chemical context

Over recent decades, the synthesis and structural characterization of transition-metal-based functional materials adopting layered or channel structures has been the focus of much scientific work. In accordance with widespread studies devoted to the improvement of those materials, we have contributed to the search for new functional materials by undertaking synthesis and structural characterization of new transition and alkali metal phosphates exhibiting channel structures and belonging to the well-known alluaudite structure type (Moore, 1971[Moore, P. B. (1971). Am. Mineral. 56, 1955-1975.]) that can be represented by the general formula A(1)A(2)M(1)M(2)2(XO4)3. The M(1) and M(2) sites accommodate di- or trivalent cations in an octa­hedral environment and are connected to the tetra­hedral XO4 groups, leading to an open-framework structure. Alluaudite-type phosphates are of special inter­est as positive electrode materials in lithium and sodium batteries. For instance, the alluaudite-type lithium manganese phosphate Li0.78Na0.22MnPO4 is proposed by Kim et al. (2014[Kim, J., Kim, H., Park, K.-Y., Park, Y.-U., Lee, S., Kwon, H.-S., Yoo, H.-I. & Kang, K. (2014). J. Mater. Chem. A, 2, 8632-8636.]) as a promising new positive electrode for Li rechargeable batteries. Furthermore, in the more active alluaudite-type cathode material for sodium-ion batteries, Na2Fe3-xMnx(PO4)3, the electrochemical performance is associated either with morphology or with the electronic and crystalline structure (Huang et al., 2015[Huang, W., Li, B., Saleem, M. F., Wu, X., Li, J., Lin, J., Xia, D., Chu, W. & Wu, Z. (2015). Chem. Eur. J. 21, 851-860.]).

Responding to the growing demand for this type of functional materials, we were able to prepare new alluaudite-type phosphates within pseudo-ternary A2O/MO/P2O5 or pseudo-quaternary A2O/MO/Fe2O3/P2O5 systems by means of hydro­thermal or solid-state reactions: AgMg3(HPO4)2PO4 (Assani et al., 2011[Assani, A., Saadi, M., Zriouil, M. & El Ammari, L. (2011). Acta Cryst. E67, i5.]), NaMg3(HPO4)2PO4 (Ould Saleck et al., 2015[Ould Saleck, A., Assani, A., Saadi, M., Mercier, C., Follet, C. & El Ammari, L. (2015). Acta Cryst. E71, 813-815.]), Na2Co2Fe(PO4)3 (Bouraima et al., 2015[Bouraima, A., Assani, A., Saadi, M., Makani, T. & El Ammari, L. (2015). Acta Cryst. E71, 558-560.]) and Na1.67Zn1.67Fe1.33(PO4)3 (Khmiyas et al., 2015[Khmiyas, J., Assani, A., Saadi, M. & El Ammari, L. (2015). Acta Cryst. E71, 690-692.]).

Besides well-known phosphate phases, arsenates (Đorđević et al., 2015[Đorđević, T., Wittwer, A. & Krivovichev, S. (2015). Eur. J. Mineral. 27, 559-573.]; Stock & Bein, 2003[Stock, N. & Bein, T. (2003). Solid State Sci. 5, 1207-1210.]) and more recently molybdates (Nasri et al., 2014[Nasri, R., Fakhar Bourguiba, N., Zid, M. F. & Driss, A. (2014). Acta Cryst. E70, i47-i48.]; Savina et al., 2014[Savina, A., Solodovnikov, S., Belov, D., Basovich, O., Solodovnikova, Z., Pokholok, K., Stefanovich, S., Lazoryak, B. & Khaikina, E. (2014). J. Solid State Chem. 220, 217-220.]) and sulfates (Oyama et al., 2015[Oyama, G., Nishimura, S., Suzuki, Y., Okubo, M. & Yamada, A. (2015). ChemElectroChem, 2, 1019-1023.]; Ming et al., 2015[Ming, J., Barpanda, P., Nishimura, S., Okubo, M. & Yamada, A. (2015). Electrochem. Commun. 51, 19-22.]) have been reported to crystallize with alluaudite-type structures. However, to the best of our knowledge, no vanadate adopting this type of structure has been reported so far. Therefore we performed hydro­thermal and solid-state reaction investigations within the A2O/MO/M2O3/V2O5 system (A = monovalent cation, M = bivalent cation and M′ = trivalent cation) with approximate molar ratios of A:M:M′:V = 2:2:1:3 and report here details of the preparation and structural characterization of the first sodium- manganese- and iron-based vanadate with an alluaudite-type structure, viz. (Na0.70)(Na0.70,Mn0.30)(Fe3+,Fe2+)2Fe2+(VO4)3.

2. Structural commentary

The preparation of this compound by melting a mixture of three metal oxide precursors in addition to vanadium oxide forced us to explore several crystallographic models. Refinement of the occupancy ratios, bond-valence analysis and the electrical neutrality requirement of the structure lead to the given composition for the title compound. The basic building units of the structure are shown in Fig. 1[link]. The structure is characterized by disorder in three positions. Fe12+ and Fe13+ are statistically distributed on a general site (Wyckoff position 8f); Na1+ and Mn12+ are disordered in a 0.7:0.3 ratio on a site located on an inversion centre (4b), and Na2+ is present at a site on a twofold rotation axis (4e) with 70% occupancy. All other sites are fully occupied. Nearly the same cationic distribution was reported by Yakubovich et al. (1977[Yakubovich, O. V., Simonov, M. A., Egorov-Tismenko, Yu. K. & Belov, N. V. (1977). Sov. Phys. Dokl. 22, 550-552.]) for the alluaudite-type phosphate Na2(Fe3+,Fe2+)2Fe2+(PO4)3.

[Figure 1]
Figure 1
The principal building units in the structure of the title compound. Displacement ellipsoids are drawn at the 50% probability level. [Symmetry codes: (i) x, −y + 1, z + [{1\over 2}]; (ii) x, y, z + 1; (iii) −x + [{1\over 2}], −y + [{3\over 2}], −z + 2; (iv) −x + [{1\over 2}], −y + [{3\over 2}], −z + 1; (v) −x, y, −z + [{3\over 2}]; (vi) x, y, z − 1; (vii) x − [{1\over 2}], −y + [{3\over 2}], z − [{1\over 2}]; (viii) −x, y, −z + [{1\over 2}]; (ix) −x, −y + 1, −z + 1; (x) x, −y + 1, z − [{1\over 2}]; (xi) −x + 1, y, −z + [{3\over 2}]; (xii) −x + 1, −y + 1, −z + 1.]

The crystal structure of the title compound is built up from edge-sharing [FeO6] octa­hedra, leading to the formation of kinked chains running along [10[\overline{1}]] (Fig. 2[link]). These chains are held together through the vertices of VO4 tetra­hedra, generating layers perpendicular to [010] (Fig. 3[link]). Thereby an open three-dimensional framework is formed that delimits two types of channels parallel to [001] in which the disordered (Na1+/Mn12+) and statistically occupied Na2+ cations are accommodated (Fig. 4[link]). The (Na1+,Mn12+) site has a distorted octa­hedral oxygen environment, with (Na1+,Mn12+)—O bond lengths between 2.4181 (16) and 2.5115 (15) Å. The Na2+ cation is coordinated by eight oxygen atoms with Na2—O distances in the range 2.4879 (18) to 2.982 (3) Å. The disorder of Na+ in the channels might admit ionic mobility for this material.

[Figure 2]
Figure 2
Edge-sharing [FeO6] octa­hedra forming a kinked chain running parallel to [10[\overline{1}]].
[Figure 3]
Figure 3
A layer perpendicular to [010], resulting from the connection of chains via vertices of VO4 tetra­hedra.
[Figure 4]
Figure 4
Polyhedral representation of (Na0.70)(Na0.70Mn0.30)(Fe3+/Fe2+)2Fe2+(VO4)3, showing channels running along and parallel to [001].

3. Synthesis and crystallization

The title compound was prepared by solid-state reactions in air. Sodium nitrate, metallic manganese and iron were mixed with vanadium oxide in proportions corresponding to the molar ratios Na:Mn:Fe:V = 2:2:1:3. The reaction mixture underwent several heat treatments in a platinum crucible until the melting temperature situated at about 1030 K was reached. Each thermal treatment was inter­spersed with grinding in an agate mortar. The resulting product contained black single crystals crystals of a suitable size for the X-ray diffraction study.

4. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1[link]. For the (Na1+,Mn12+) site, full occupation was assumed, with the sum of the site occupation factors constrained to be 1. The site-occupation factor of Na2+ was refined freely. In the last step of the refinement, the site occupation factors were fixed to fulfill electro-neutrality. Reflection (1 5 0) was probably affected by the beam-stop and was omitted from the refinement. The remaining maximum and minimum electron density peaks are located 0.59 and 0.41 Å from Fe2 and V2, respectively.

Table 1
Experimental details

Crystal data
Chemical formula Na1.40Mn0.30Fe3(VO4)3
Mr 561.04
Crystal system, space group Monoclinic, C2/c
Temperature (K) 296
a, b, c (Å) 11.9512 (5), 12.9022 (5), 6.7756 (3)
β (°) 111.678 (1)
V3) 970.88 (7)
Z 4
Radiation type Mo Kα
μ (mm−1) 7.63
Crystal size (mm) 0.30 × 0.26 × 0.18
 
Data collection
Diffractometer Bruker X8 APEX
Absorption correction Multi-scan (SADABS; Bruker, 2009[Bruker (2009). APEX2, SAINT and SADABS. Bruker AXS Inc., Madison, Wisconsin, USA.])
Tmin, Tmax 0.545, 0.747
No. of measured, independent and observed [I > 2σ(I)] reflections 17759, 1768, 1595
Rint 0.030
(sin θ/λ)max−1) 0.757
 
Refinement
R[F2 > 2σ(F2)], wR(F2), S 0.020, 0.056, 1.12
No. of reflections 1768
No. of parameters 100
Δρmax, Δρmin (e Å−3) 0.74, −0.99
Computer programs: APEX2 and SAINT (Bruker, 2009[Bruker (2009). APEX2, SAINT and SADABS. Bruker AXS Inc., Madison, Wisconsin, USA.]), SHELXT (Sheldrick, 2015a[Sheldrick, G. M. (2015a). Acta Cryst. A71, 3-8.]), SHELXL2014 (Sheldrick, 2015b[Sheldrick, G. M. (2015b). Acta Cryst. C71, 3-8.]), ORTEP-3 for Windows (Farrugia, 2012[Farrugia, L. J. (2012). J. Appl. Cryst. 45, 849-854.]), DIAMOND (Brandenburg, 2006[Brandenburg, K. (2006). DIAMOND. Crystal Impact GbR, Bonn, Germany.]) and publCIF (Westrip, 2010[Westrip, S. P. (2010). J. Appl. Cryst. 43, 920-925.]).

Supporting information


Chemical context top

Over recent decades, the synthesis and structural characterization of transition-metal-based functional materials adopting layered or channel structures has been the focus of much scientific work. In accordance with widespread studies devoted to the improvement of those materials, we have contributed to the search for new functional materials by undertaking synthesis and structural characterization of new transition and alkali metal phosphates exhibiting channel structures and belonging to the well known alluaudite structure type (Moore, 1971) that can be represented by the general formula A(1)A(2)M(1)M(2)2(XO4)3. The M(1) and M(2) sites accommodate di- or trivalent cations in an o­cta­hedral environment and are connected to the tetra­hedral XO4 groups, leading to an open-framework structure. Alluaudite-type phosphates are of special inter­est as positive electrode materials in lithium and sodium batteries. For instance, the alluaudite-type lithium manganese phosphate Li0.78Na0.22MnPO4 is proposed by Kim et al. (2014) as a promising new positive electrode for Li rechargeable batteries. Furthermore, in the more active alluaudite-type cathode material for sodium-ion batteries, Na2Fe3 − xMnx(PO4)3, the electrochemical performance is associated either with morphology or with the electronic and crystalline structure (Huang et al., 2015).

Responding to the growing demand for this type of functional materials, we were able to prepare new alluaudite-type phosphates within pseudo-ternary A2O/MO/P2O5 or pseudo-quaternary A2O/MO/Fe2O3—P2O5 systems by means of hydro­thermal or solid-state reactions: AgMg3(HPO4)2PO4 (Assani et al., 2011), NaMg3(HPO4)2PO4 (Ould Saleck et al., 2015), Na2Co2Fe (PO4)3 (Bouraima et al., 2015) and Na1.67Zn1.67Fe1.33(PO4)3 (Khmiyas et al., 2015).

Besides well known phosphate phases, arsenates (Đorđević et al., 2015; Stock & Bein, 2003) and more recently molybdates (Nasri et al., 2014; Savina et al., 2014) and sulfates (Oyama et al., 2015; Ming et al., 2015) have been reported to crystallize with alluaudite-type structures. However, to the best of our knowledge, no vanadate adopting this type of structure has been reported so far. Therefore we performed hydro­thermal and solid-state reaction investigations within the A2O/MO/M'2O3/V2O5 system (A = monovalent cation, M = bivalent cation and M' = trivalent cation) with approximate molar ratios of A:M:M':V = 2:2:1:3 and report here details of the preparation and structural characterization of the first sodium-, manganese- and iron-based vanadate with an alluaudite-type structure, viz. (Na0.70)(Na0.70,Mn0.30)(Fe3+,Fe2+)2Fe2+(VO4)3.

Structural commentary top

The preparation of this compound by melting a mixture of three metal oxide precursors in addition to vanadium oxide forced us to explore several crystallographic models. Refinement of the occupancy ratios, bond-valence analysis and the electrical neutrality requirement of the structure lead to the given composition for the title compound. The basic building units of the structure are shown in Fig. 1. The structure is characterized by disorder in three positions. Fe12+ and Fe13+ are statistically distributed on a general site (Wyckoff position 8f); Na1+ and Mn12+ are disordered in a 0.7:0.3 ratio on a site located on an inversion centre (4b), and Na2+ is present at a site on a twofold rotation axis (4e) with 70% occupancy. All other sites are fully occupied. Nearly the same cationic distribution was reported by Yakubovich et al. (1977) for the alluaudite-type phosphate Na2(Fe3+,Fe2+)2Fe2+(PO4)3.

The crystal structure of the title compound is built up from edge-sharing [FeO6] o­cta­hedra, leading to the formation of kinked chains running along [101] (Fig. 2). These chains are held together through the vertices of VO4 tetra­hedra, generating layers perpendicular to [010] (Fig. 3). Thereby an open three-dimensional framework is formed that delimits two types of channels parallel to [001] in which the disordered (Na1+/Mn12+) and statistically occupied Na2+ cations are accommodated (Fig. 4). The (Na1+,Mn12+) site has a distorted o­cta­hedral oxygen environment, with (Na1+,Mn12+)—O bond lengths between 2.4181 (16) and 2.5115 (15) Å. The Na2+ cation is coordinated by eight oxygen atoms with Na2—O distances in the range 2.4879 (18) to 2.982 (3) Å. The disorder of Na+ in the channels might admit ionic mobility for this material.

Synthesis and crystallization top

The title compound was prepared by solid-state reactions in air. Sodium nitrate, metallic manganese and iron were mixed with vanadium oxide in proportions corresponding to the molar ratios Na:Mn:Fe:V = 2:2:1:3. The reaction mixture underwent several heat treatments in a platinum crucible until the melting temperature situated at about 1030 K was reached. Each thermal treatment was inter­spersed with grinding in an agate mortar. The resulting product contained black single crystals crystals of a suitable size for the X-ray diffraction study.

Refinement top

Crystal data, data collection and structure refinement details are summarized in Table 1. For the (Na1+,Mn12+) site, full occupation was assumed, with the sum of the site occupation factors constrained to be 1. The site-occupation factor of Na2+ was refined freely. In the last step of the refinement, the site occupation factors were fixed to fulfill electro-neutrality. Reflection (1 5 0) was probably affected by the beam-stop and was omitted from the refinement. The remaining maximum and minimum electron density peaks are located 0.59 and 0.41 Å from Fe2 and V2, respectively.

Structure description top

Over recent decades, the synthesis and structural characterization of transition-metal-based functional materials adopting layered or channel structures has been the focus of much scientific work. In accordance with widespread studies devoted to the improvement of those materials, we have contributed to the search for new functional materials by undertaking synthesis and structural characterization of new transition and alkali metal phosphates exhibiting channel structures and belonging to the well known alluaudite structure type (Moore, 1971) that can be represented by the general formula A(1)A(2)M(1)M(2)2(XO4)3. The M(1) and M(2) sites accommodate di- or trivalent cations in an o­cta­hedral environment and are connected to the tetra­hedral XO4 groups, leading to an open-framework structure. Alluaudite-type phosphates are of special inter­est as positive electrode materials in lithium and sodium batteries. For instance, the alluaudite-type lithium manganese phosphate Li0.78Na0.22MnPO4 is proposed by Kim et al. (2014) as a promising new positive electrode for Li rechargeable batteries. Furthermore, in the more active alluaudite-type cathode material for sodium-ion batteries, Na2Fe3 − xMnx(PO4)3, the electrochemical performance is associated either with morphology or with the electronic and crystalline structure (Huang et al., 2015).

Responding to the growing demand for this type of functional materials, we were able to prepare new alluaudite-type phosphates within pseudo-ternary A2O/MO/P2O5 or pseudo-quaternary A2O/MO/Fe2O3—P2O5 systems by means of hydro­thermal or solid-state reactions: AgMg3(HPO4)2PO4 (Assani et al., 2011), NaMg3(HPO4)2PO4 (Ould Saleck et al., 2015), Na2Co2Fe (PO4)3 (Bouraima et al., 2015) and Na1.67Zn1.67Fe1.33(PO4)3 (Khmiyas et al., 2015).

Besides well known phosphate phases, arsenates (Đorđević et al., 2015; Stock & Bein, 2003) and more recently molybdates (Nasri et al., 2014; Savina et al., 2014) and sulfates (Oyama et al., 2015; Ming et al., 2015) have been reported to crystallize with alluaudite-type structures. However, to the best of our knowledge, no vanadate adopting this type of structure has been reported so far. Therefore we performed hydro­thermal and solid-state reaction investigations within the A2O/MO/M'2O3/V2O5 system (A = monovalent cation, M = bivalent cation and M' = trivalent cation) with approximate molar ratios of A:M:M':V = 2:2:1:3 and report here details of the preparation and structural characterization of the first sodium-, manganese- and iron-based vanadate with an alluaudite-type structure, viz. (Na0.70)(Na0.70,Mn0.30)(Fe3+,Fe2+)2Fe2+(VO4)3.

The preparation of this compound by melting a mixture of three metal oxide precursors in addition to vanadium oxide forced us to explore several crystallographic models. Refinement of the occupancy ratios, bond-valence analysis and the electrical neutrality requirement of the structure lead to the given composition for the title compound. The basic building units of the structure are shown in Fig. 1. The structure is characterized by disorder in three positions. Fe12+ and Fe13+ are statistically distributed on a general site (Wyckoff position 8f); Na1+ and Mn12+ are disordered in a 0.7:0.3 ratio on a site located on an inversion centre (4b), and Na2+ is present at a site on a twofold rotation axis (4e) with 70% occupancy. All other sites are fully occupied. Nearly the same cationic distribution was reported by Yakubovich et al. (1977) for the alluaudite-type phosphate Na2(Fe3+,Fe2+)2Fe2+(PO4)3.

The crystal structure of the title compound is built up from edge-sharing [FeO6] o­cta­hedra, leading to the formation of kinked chains running along [101] (Fig. 2). These chains are held together through the vertices of VO4 tetra­hedra, generating layers perpendicular to [010] (Fig. 3). Thereby an open three-dimensional framework is formed that delimits two types of channels parallel to [001] in which the disordered (Na1+/Mn12+) and statistically occupied Na2+ cations are accommodated (Fig. 4). The (Na1+,Mn12+) site has a distorted o­cta­hedral oxygen environment, with (Na1+,Mn12+)—O bond lengths between 2.4181 (16) and 2.5115 (15) Å. The Na2+ cation is coordinated by eight oxygen atoms with Na2—O distances in the range 2.4879 (18) to 2.982 (3) Å. The disorder of Na+ in the channels might admit ionic mobility for this material.

Synthesis and crystallization top

The title compound was prepared by solid-state reactions in air. Sodium nitrate, metallic manganese and iron were mixed with vanadium oxide in proportions corresponding to the molar ratios Na:Mn:Fe:V = 2:2:1:3. The reaction mixture underwent several heat treatments in a platinum crucible until the melting temperature situated at about 1030 K was reached. Each thermal treatment was inter­spersed with grinding in an agate mortar. The resulting product contained black single crystals crystals of a suitable size for the X-ray diffraction study.

Refinement details top

Crystal data, data collection and structure refinement details are summarized in Table 1. For the (Na1+,Mn12+) site, full occupation was assumed, with the sum of the site occupation factors constrained to be 1. The site-occupation factor of Na2+ was refined freely. In the last step of the refinement, the site occupation factors were fixed to fulfill electro-neutrality. Reflection (1 5 0) was probably affected by the beam-stop and was omitted from the refinement. The remaining maximum and minimum electron density peaks are located 0.59 and 0.41 Å from Fe2 and V2, respectively.

Computing details top

Data collection: APEX2 (Bruker, 2009); cell refinement: SAINT (Bruker, 2009); data reduction: SAINT (Bruker, 2009); program(s) used to solve structure: SHELXT (Sheldrick, 2015a); program(s) used to refine structure: SHELXL2014 (Sheldrick, 2015b); molecular graphics: ORTEP-3 for Windows (Farrugia, 2012) and DIAMOND (Brandenburg, 2006); software used to prepare material for publication: publCIF (Westrip, 2010).

Figures top
[Figure 1] Fig. 1. The principal building units in the structure of the title compound. Displacement ellipsoids are drawn at the 50% probability level. [Symmetry codes: (i) x, −y + 1, z + 1/2; (ii) x, y, z + 1; (iii) −x + 1/2, −y + 3/2, −z + 2; (iv) −x + 1/2, −y + 3/2, −z + 1; (v) −x, y, −z + 3/2; (vi) x, y, z − 1; (vii) x − 1/2, −y + 3/2, z − 1/2; (viii) −x, y, −z + 1/2; (ix) −x, −y + 1, −z + 1; (x) x, −y + 1, z − 1/2; (xi) −x + 1, y, −z + 3/2; (xii) −x + 1, −y + 1, −z + 1.]
[Figure 2] Fig. 2. Edge-sharing [FeO6] octahedra forming a kinked chain running parallel to [101].
[Figure 3] Fig. 3. A layer perpendicular to [010], resulting from the connection of chains via vertices of VO4 tetrahedra.
[Figure 4] Fig. 4. Polyhedral representation of (Na0.70)(Na0.70Mn0.30)(Fe3+/Fe2+)2Fe2+(VO4)3, showing channels running along and parallel to [001].
Sodium (sodium,manganese) triiron(II,III) tris[vanadate(V)] top
Crystal data top
Na1.40Mn0.30Fe3(VO4)3F(000) = 1064
Mr = 561.04Dx = 3.838 Mg m3
Monoclinic, C2/cMo Kα radiation, λ = 0.71073 Å
a = 11.9512 (5) ÅCell parameters from 1768 reflections
b = 12.9022 (5) Åθ = 2.4–32.6°
c = 6.7756 (3) ŵ = 7.63 mm1
β = 111.678 (1)°T = 296 K
V = 970.88 (7) Å3Block, black
Z = 40.30 × 0.26 × 0.18 mm
Data collection top
Bruker X8 APEX
diffractometer
1768 independent reflections
Radiation source: fine-focus sealed tube1595 reflections with I > 2σ(I)
Graphite monochromatorRint = 0.030
φ and ω scansθmax = 32.6°, θmin = 2.4°
Absorption correction: multi-scan
(SADABS; Bruker, 2009)
h = 1818
Tmin = 0.545, Tmax = 0.747k = 1919
17759 measured reflectionsl = 710
Refinement top
Refinement on F2100 parameters
Least-squares matrix: full0 restraints
R[F2 > 2σ(F2)] = 0.020 w = 1/[σ2(Fo2) + (0.0252P)2 + 2.9028P]
where P = (Fo2 + 2Fc2)/3
wR(F2) = 0.056(Δ/σ)max = 0.001
S = 1.12Δρmax = 0.74 e Å3
1768 reflectionsΔρmin = 0.99 e Å3
Crystal data top
Na1.40Mn0.30Fe3(VO4)3V = 970.88 (7) Å3
Mr = 561.04Z = 4
Monoclinic, C2/cMo Kα radiation
a = 11.9512 (5) ŵ = 7.63 mm1
b = 12.9022 (5) ÅT = 296 K
c = 6.7756 (3) Å0.30 × 0.26 × 0.18 mm
β = 111.678 (1)°
Data collection top
Bruker X8 APEX
diffractometer
1768 independent reflections
Absorption correction: multi-scan
(SADABS; Bruker, 2009)
1595 reflections with I > 2σ(I)
Tmin = 0.545, Tmax = 0.747Rint = 0.030
17759 measured reflections
Refinement top
R[F2 > 2σ(F2)] = 0.020100 parameters
wR(F2) = 0.0560 restraints
S = 1.12Δρmax = 0.74 e Å3
1768 reflectionsΔρmin = 0.99 e Å3
Special details top

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

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Fe10.28812 (3)0.65986 (2)0.87842 (4)0.00988 (7)
Fe20.00000.73519 (3)0.25000.01105 (9)
V10.26720 (3)0.61038 (2)0.37946 (5)0.00884 (7)
V20.00000.71081 (4)0.75000.01126 (10)
Mn10.00000.50000.50000.0136 (8)0.3
Na10.00000.50000.50000.0420 (18)0.7
Na20.50000.4890 (3)0.75000.0432 (7)0.7
O10.12025 (14)0.59837 (11)0.3264 (3)0.0151 (3)
O20.28070 (14)0.68158 (12)0.1709 (2)0.0160 (3)
O30.33564 (14)0.67141 (12)0.6228 (2)0.0148 (3)
O40.11010 (16)0.62915 (12)0.7570 (3)0.0194 (3)
O50.03980 (14)0.78286 (12)0.9783 (2)0.0138 (3)
O60.33208 (16)0.49277 (13)0.3977 (3)0.0189 (3)
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Fe10.01049 (13)0.01185 (12)0.00849 (13)0.00026 (9)0.00491 (10)0.00052 (9)
Fe20.00964 (17)0.01269 (17)0.01294 (19)0.0000.00665 (14)0.000
V10.00876 (14)0.01060 (14)0.00697 (15)0.00061 (10)0.00267 (11)0.00072 (10)
V20.0160 (2)0.00896 (18)0.0073 (2)0.0000.00244 (16)0.000
Mn10.0196 (17)0.0093 (18)0.0073 (18)0.0076 (13)0.0005 (14)0.0011 (13)
Na10.059 (4)0.027 (4)0.033 (4)0.001 (3)0.009 (3)0.001 (3)
Na20.0216 (12)0.0687 (19)0.0345 (14)0.0000.0047 (10)0.000
O10.0108 (6)0.0137 (6)0.0201 (8)0.0008 (5)0.0049 (6)0.0013 (5)
O20.0160 (7)0.0203 (7)0.0119 (7)0.0020 (5)0.0053 (6)0.0005 (5)
O30.0176 (7)0.0142 (6)0.0117 (7)0.0049 (5)0.0043 (5)0.0007 (5)
O40.0234 (8)0.0136 (6)0.0163 (7)0.0027 (6)0.0015 (6)0.0045 (5)
O50.0116 (6)0.0177 (6)0.0124 (7)0.0003 (5)0.0048 (5)0.0003 (5)
O60.0173 (7)0.0200 (7)0.0191 (8)0.0024 (6)0.0063 (6)0.0056 (6)
Geometric parameters (Å, º) top
Fe1—O42.0167 (18)Mn1—O4ix2.4181 (16)
Fe1—O32.0180 (16)Mn1—O42.4181 (16)
Fe1—O6i2.0299 (17)Mn1—O1i2.4941 (16)
Fe1—O2ii2.0358 (16)Mn1—O1viii2.4941 (16)
Fe1—O5iii2.0599 (16)Mn1—O12.5115 (15)
Fe1—O2iv2.1841 (16)Mn1—O1ix2.5115 (15)
Fe2—O5v2.1540 (15)Na1—O4ix2.4181 (16)
Fe2—O5vi2.1540 (15)Na1—O42.4181 (16)
Fe2—O3iv2.1915 (15)Na1—O1i2.4941 (16)
Fe2—O3vii2.1915 (15)Na1—O1viii2.4941 (16)
Fe2—O1viii2.2136 (15)Na1—O12.5115 (15)
Fe2—O12.2136 (15)Na1—O1ix2.5115 (15)
V1—O11.6647 (15)Na1—O4x2.9698 (18)
V1—O61.6878 (16)Na1—O4v2.9698 (18)
V1—O31.7351 (16)Na2—O6xi2.4879 (18)
V1—O21.7420 (16)Na2—O62.4879 (18)
V2—O41.6726 (17)Na2—O6xii2.5627 (18)
V2—O4v1.6726 (17)Na2—O6i2.5627 (18)
V2—O51.7147 (15)Na2—O3xi2.982 (3)
V2—O5v1.7147 (15)Na2—O32.982 (3)
O4—Fe1—O3104.67 (7)O1i—Mn1—O1115.50 (6)
O4—Fe1—O6i92.56 (7)O1viii—Mn1—O164.50 (6)
O3—Fe1—O6i88.77 (7)O4ix—Mn1—O1ix74.67 (6)
O4—Fe1—O2ii90.31 (7)O4—Mn1—O1ix105.33 (6)
O3—Fe1—O2ii162.33 (6)O1i—Mn1—O1ix64.50 (6)
O6i—Fe1—O2ii100.04 (7)O1viii—Mn1—O1ix115.50 (6)
O4—Fe1—O5iii169.09 (6)O1—Mn1—O1ix180.00 (6)
O3—Fe1—O5iii80.18 (6)O4ix—Na1—O4180.0
O6i—Fe1—O5iii97.36 (7)O4ix—Na1—O1i105.66 (5)
O2ii—Fe1—O5iii83.50 (6)O4—Na1—O1i74.34 (5)
O4—Fe1—O2iv80.83 (6)O4ix—Na1—O1viii74.34 (5)
O3—Fe1—O2iv90.51 (6)O4—Na1—O1viii105.66 (5)
O6i—Fe1—O2iv172.94 (7)O1i—Na1—O1viii180.0
O2ii—Fe1—O2iv82.57 (6)O4ix—Na1—O1105.33 (6)
O5iii—Fe1—O2iv89.43 (6)O4—Na1—O174.67 (6)
O5v—Fe2—O5vi146.82 (8)O1i—Na1—O1115.50 (6)
O5v—Fe2—O3iv87.45 (6)O1viii—Na1—O164.50 (6)
O5vi—Fe2—O3iv74.36 (6)O4ix—Na1—O1ix74.67 (6)
O5v—Fe2—O3vii74.36 (6)O4—Na1—O1ix105.33 (6)
O5vi—Fe2—O3vii87.45 (6)O1i—Na1—O1ix64.50 (6)
O3iv—Fe2—O3vii113.28 (8)O1viii—Na1—O1ix115.50 (6)
O5v—Fe2—O1viii95.65 (6)O1—Na1—O1ix180.00 (6)
O5vi—Fe2—O1viii110.91 (6)O4ix—Na1—O4x56.55 (7)
O3iv—Fe2—O1viii160.16 (6)O4—Na1—O4x123.45 (7)
O3vii—Fe2—O1viii86.35 (6)O1i—Na1—O4x88.74 (5)
O5v—Fe2—O1110.91 (6)O1viii—Na1—O4x91.26 (5)
O5vi—Fe2—O195.65 (6)O1—Na1—O4x64.95 (5)
O3iv—Fe2—O186.35 (6)O1ix—Na1—O4x115.05 (5)
O3vii—Fe2—O1160.16 (6)O4ix—Na1—O4v123.45 (7)
O1viii—Fe2—O174.22 (8)O4—Na1—O4v56.55 (7)
O1—V1—O6110.59 (8)O1i—Na1—O4v91.26 (5)
O1—V1—O3109.68 (8)O1viii—Na1—O4v88.74 (5)
O6—V1—O3107.22 (8)O1—Na1—O4v115.05 (5)
O1—V1—O2106.29 (8)O1ix—Na1—O4v64.95 (5)
O6—V1—O2110.84 (8)O4x—Na1—O4v180.0
O3—V1—O2112.27 (7)O6xi—Na2—O6177.75 (17)
O4—V2—O4v101.92 (12)O6xi—Na2—O6xii84.40 (5)
O4—V2—O5111.28 (8)O6—Na2—O6xii95.40 (5)
O4v—V2—O5108.67 (8)O6xi—Na2—O6i95.40 (5)
O4—V2—O5v108.67 (8)O6—Na2—O6i84.40 (5)
O4v—V2—O5v111.28 (8)O6xii—Na2—O6i169.46 (16)
O5—V2—O5v114.33 (10)O6xi—Na2—O3xi59.69 (6)
O4ix—Mn1—O4180.0O6—Na2—O3xi118.28 (11)
O4ix—Mn1—O1i105.66 (5)O6xii—Na2—O3xi60.86 (6)
O4—Mn1—O1i74.34 (5)O6i—Na2—O3xi109.99 (10)
O4ix—Mn1—O1viii74.34 (5)O6xi—Na2—O3118.28 (11)
O4—Mn1—O1viii105.66 (5)O6—Na2—O359.69 (6)
O1i—Mn1—O1viii180.0O6xii—Na2—O3109.99 (10)
O4ix—Mn1—O1105.33 (6)O6i—Na2—O360.86 (6)
O4—Mn1—O174.67 (6)O3xi—Na2—O375.74 (10)
Symmetry codes: (i) x, y+1, z+1/2; (ii) x, y, z+1; (iii) x+1/2, y+3/2, z+2; (iv) x+1/2, y+3/2, z+1; (v) x, y, z+3/2; (vi) x, y, z1; (vii) x1/2, y+3/2, z1/2; (viii) x, y, z+1/2; (ix) x, y+1, z+1; (x) x, y+1, z1/2; (xi) x+1, y, z+3/2; (xii) x+1, y+1, z+1.

Experimental details

Crystal data
Chemical formulaNa1.40Mn0.30Fe3(VO4)3
Mr561.04
Crystal system, space groupMonoclinic, C2/c
Temperature (K)296
a, b, c (Å)11.9512 (5), 12.9022 (5), 6.7756 (3)
β (°) 111.678 (1)
V3)970.88 (7)
Z4
Radiation typeMo Kα
µ (mm1)7.63
Crystal size (mm)0.30 × 0.26 × 0.18
Data collection
DiffractometerBruker X8 APEX
Absorption correctionMulti-scan
(SADABS; Bruker, 2009)
Tmin, Tmax0.545, 0.747
No. of measured, independent and
observed [I > 2σ(I)] reflections
17759, 1768, 1595
Rint0.030
(sin θ/λ)max1)0.757
Refinement
R[F2 > 2σ(F2)], wR(F2), S 0.020, 0.056, 1.12
No. of reflections1768
No. of parameters100
Δρmax, Δρmin (e Å3)0.74, 0.99

Computer programs: APEX2 (Bruker, 2009), SAINT (Bruker, 2009), SHELXT (Sheldrick, 2015a), SHELXL2014 (Sheldrick, 2015b), ORTEP-3 for Windows (Farrugia, 2012) and DIAMOND (Brandenburg, 2006), publCIF (Westrip, 2010).

 

Acknowledgements

The authors thank the Unit of Support for Technical and Scientific Research (UATRS, CNRST) for the X-ray measurements and Mohammed V University, Rabat, Morocco, for financial support.

References

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Volume 72| Part 2| February 2016| Pages 220-222
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