New Data on the Isomorphism in Eudialyte-Group Minerals. 1. Crystal Chemistry of Eudialyte-Group Members with Na Incorporated into the Framework as a Marker of Hyperagpaitic Conditions

Abstract

A review of the crystal chemistry of Fe-deficient eudialyte-group minerals is given. Specific features of cation distribution over key sites in the crystal structure, including partial substitution of Fe²⁺ with Na, Mn and Zr at the M2 site are discussed. It is concluded that Na-dominant (at the M2 site) eudialyte-group members (^M2Na-EGMs) are markers of specific kinds of specific peralkaline (hyperagpaitic) igneous rocks and pegmatites. New data are obtained on the chemical composition, IR spectra and crystal chemistry for two samples of ^M2Na-EGMs with disordered M1 cations, which are a potentially new mineral species with the simplified formula (Na,H₂O)₁₅Ca₆Zr₃[Na₂(Fe,Zr)][Si₂₆O₇₂](OH)₂Cl·nH₂O.

1. Introduction

Eudialyte, ideally Na₁₅Ca₆Fe²⁺₃Zr₃(Si₂₆O₇₃)(O,OH,H₂O)₃(Cl,OH)₂ (Z = 3), is the most important zirconosilicate mineral. It was discovered two hundred years ago in the Ilímaussaq alkaline complex, South Greenland [1], and later, numerous other finds of eudialyte and related mineral species defined as eudialyte-group members were described. Eudialyte-bearing rocks are considered as a potential source of different rare elements (Zr, Hf, Nb, Y, lanthanides, etc.); the largest reserves of such rocks with potential industrial significance are in the Lovozero alkaline complex, Kola Peninsula, Russia, and in the Ilímaussaq complex.

The crystal structures of eudialyte-group minerals (EGMs, Figure 1) are based on a heteropolyhedral framework {M1₆M2₃Z₃[Si₃O₉]₂[Si₉O₂₇]₂} consisting of 9- and 3-membered rings of tetrahedra (Si₉O₂₇, Si₃O₉) and 6-membered rings of octahedra M1₆O₂₄ (M1 = Ca, Mn²⁺, Fe²⁺, Na, Ln, Sr where Ln are lanthanides), linked via isolated ZO₆ octahedra (Z = Zr, Ti) and ^[4–7]M2O_n polyhedra (M2 = Fe²⁺, Fe³⁺, Mn²⁺, Na, Zr, etc.; coordination numbers are indicated in square brackets). Additional sites (M3 and M4) located at the centers of the Si₉O₂₇ rings are occupied by ^[4]Si, ^[6]Nb, rarely ^[6]W, and some other components, and can be partly vacant. Actually, the key sites M2, M3 and M4 are microregions, each of which can contain several close-spaced sites with different coordinations. For eudialyte sensu stricto, the formula of the framework is {Ca₆Fe²⁺₃Zr₃[Si₃O₉]₂[Si₉O₂₇]₂}^18–.

Different schemes of homovalent, heterovalent and blocky isomorphism can occur in eudialyte-type structures, which results in the unique crystal-chemical diversity of eudialyte and related minerals. At present, the eudialyte group includes 29 recognized mineral species [2,3,4,5,6,7,8]. During the last five years, a lot of new data on the crystal chemistry and properties of these minerals have been published [9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31], and three new mineral species belonging to the eudialyte group have been discovered: ilyukhinite (H₃O,Na)₁₄Ca₆Mn²⁺₂Zr₃Si₂₆O₇₂(OH)₂·3H₂O [11], siudaite Na₈Mn²⁺₃Ca₆(Fe³⁺,Mn²⁺)₃Zr₃NbSi₂₄(Si,☐,Ti)O₇₂(O,OH)₃Cl·4H₂O [19] and sergevanite Na₁₅(Ca₃Mn²⁺₃)(Na₂Fe²⁺)Zr₃Si₂₆O₇₂(OH)₃·H₂O (IMA 2019-057). Simplified crystal chemical formulae of eudialyte-group minerals are given in

Table 1. Simplified crystal chemical formulae of eudialyte group minerals, including potentially new species (Samples 1 and 2). The key sites are indicated.

Mineral	Simplified formula (Z = 3)
Eudialyte	N1-N5Na15M1Ca6M2Fe2+3ZZr3M3,M4[Si2] [Si24O72](O,OH,H2O)3(Cl,OH)2
Mangano- eudialyte	N1-N5Na14M1Ca6M2Mn3ZZr3M3,M4[Si2] (Si24O72)[(OH)2Cl2]·4H2O
Fengchenite	N1-N5 [Na12☐3]M1(Ca,Sr)6 M2Fe3+3 ZZr3 M3,M4[Si2] (Si24O72)(H2O,OH,O)3(OH,Cl)2
Feklichevite	N1-N5[Na11Ca3] M1Ca6M2Fe3+2ZZr3M3,M4[SiNb] (Si24O72)(OH,H2O,Cl,O)5
Golyshevite	N1-N5[(Na,Ca)10 Ca3] M1Ca6 M2Fe3+2 ZZr3 M3,M4[SiNb] (Si24O72)(CO3)(OH)3·H2O
Taseqite	N1-N5(Na12Sr3) M1Ca6M2Fe2+3ZZr3M3,M4[SiNb] (Si24O72)(O,OH,H2O)4Cl2
Mogovidite	N1-N5[Na9(Ca,Na)6] M1Ca6M2Fe3+2ZZr3M3,M4[☐Si] (Si24O72)CO3)(OH,H2O)
Voronkovite	N1-N5Na15M1[(Na,Ca,Ce)3(Mn,Ca)3] M2Fe2+3ZZr3M3,M4[Si2] (Si24O72)(OH,O)4Cl·H2O
Georgbarsanovite	N1-N5[Na12 Mn3] M1Ca6 M2Fe2+3 ZZr3 M3,M4[SiNb] (Si24O72)(O,OH,F)4Cl·H2O
Kentbrooksite	N1-N5(Na,REE)15M1(Ca,REE)6M2Mn3ZZr3M3,M4[SiNb] (Si24O74)F2·2H2O
Ferrokent- brooksite	N1-N5 Na15 M1Ca6 M2Fe2+3 ZZr3 M3,M4[SiNb] (Si24O73)(O,OH,H2O)4(Cl,F,OH)2
Carbokent- brooksite	N1-N5(Na,☐,REE)15M1Ca6M2Mn3ZZr3M3,M4[SiNb] (Si24O74)O(OH)3(CO3)·H2O
Zirsilite-(Ce)	N1-N5[(Na,☐)12(Ce,Na)3] M1Ca6M2Mn3ZZr3M3,M4[SiNb] (Si24O74)O(OH)3(CO3)·H2O
Ikranite	N1-N5(Na,H3O)15M1(Ca,Mn,REE)6M2Fe3+ZZr3M3,M4[(☐,Zr)(☐,Si)] Si24O66(O,OH)6Cl·nH2O
Andrianovite	N1-N5[Na12(K,Sr,Ce)3 ] M1Ca6 M2Mn3ZZr3 M3,M4[SiNb] (Si24O73)(O,H2O,OH)5
Davinciite	N1-N5[Na12K3] M1Ca6M2Fe2+3ZZr3M3,M4[Si2] [(Si24O73OH)]Cl2
Ilyukhinite	N1-N5(H3O,Na)14M1Ca6 Mn2+2 ZZr3 M3,M4[Si2] [Si24O72(OH)2]·3H2O
Siudaite	N1-N5[(Na,H2O)12(Mn2+,Na)3] M1Ca6M2(Fe3+2Mn2+) ZZr3M3,M4[SiNb] [Si24O70(OH)2] (OH,O,H2O)5
Raslakite	N1-N5Na15M1[Ca3Fe3] M2(Na,Zr)3ZZr3M3,M4[(Si,Nb)Si] (Si24O72) (OH,H2O,O)4(Cl,OH)
Sergevanite	N1-N5(Na,H3O)15M1(Ca3Mn2+3) M2(Na2Fe2+) ZZr3M3,M4[Si(Si,Ti)] [Si24O72] (OH,H2O,SO4)5
Aqualite	N1-N5[(H3O)9 (K,Ba,Sr)2] M1Ca6 ZZr3 M2Na2 M3,M4[Si2] [Si24O66(OH)6](OH)3Cl·H2O
Oneillite	N1-N5 Na15 M1[Ca3Mn3] M2Fe3 ZZr3 M3,M4[SiNb] (Si24O72)(O,OH,H2O)4(Cl,OH)2
Khomyakovite	N1-N5[Na12Sr3] M1Ca6M2Fe3ZZr3M3,M4[SiW] (Si24O72)(O,OH,H2O)4(OH,Cl)2
Mangano- khomyakovite	N1-N5[Na12Sr3] M1Ca6M2Mn3ZZr3M3,M4[SiW] (Si24O72)(O,OH,H2O)4(OH,Cl)2
Johnsenite-(Ce)	N1-N5[Na12(Ce,La,Sr,Ca,☐)3] M1Ca6M2Mn3ZZr3M3,M4[SiW] (Si24O72) (CO3)(O,OH,Cl)3
Alluaivite	N1-N5(Na,☐)30M1(Ca,Mn)12M2Na4.6M3,M4Si4Z(Ti,Nb)6 [Si24O72]2 Cl2·nH2O
Dualite	N1-N5Na30M1(Ca,Na,Ce,Sr)12M2(Na,Mn,Fe,Ti) 6Z[Zr3Ti3] M3,M4[MnSi3] [Si48O144](OH,H2O,Cl]9
Labyrinthite	N1-N5Na32M1Ca12M2[Na3Fe2☐] ZZr6M3,M4[Si3Ti] [Si3O9]4[Si9O27]4(O,OH)9Cl3
Rastsvetaevite	N1-N5[Na26K6] M1Ca12M2[NaK2Fe3] ZZr6M3,M4[Si4] [Si3O9]4[Si9O27]4 (O,OH,H2O)6Cl
Sample 1	N1-N5(Na,H3O)13M1(Ca,Mn)6) ZZr3M2[Na2Zr] M3,M4[Si2] [Si24O72](OH)2Cl·H2O
Sample 2	N1-N5(Na,H3O)15M1Ca6ZZr3M2[Na2Fe] M3,M4[Si2][Si24O72](OH)2Cl·2H2O

Note: For some minerals, components other than Na occurring at the N1–5 sites are separated from Na with brackets because these components are ordered at the N3 and N4 sites.

.

This paper summarizes structural data on EGMs in which Na prevails at the M2 site (below – ^M2Na-EGMs). To date, the crystal structures of 23 samples of ^M2Na-EGMs have been published. In this paper, we discuss the crystal chemical features of these minerals and provide some additional (chemical, IR spectroscopic and detailed crystal chemical) data on two samples of Fe-deficient EGMs whose crystal structures were reported elsewhere [24,31]. In addition, the significance of ^M2Na-EGMs as markers of hyperagpaitic rocks is discussed.

2. Materials and Methods

Sample 1 (sample Kdk-6626) was collected from the Kedykverpakhk area of the Karnasurt underground loparite mine at Mt. Kedykverpakhk in the northwest part of the Lovozero alkaline massif. The studied EGM occurs as transparent, reddish, equant grains up to 1.5 mm across in a peralkaline (hyperagpaitic) foyaite near the contact point with the loparite malignite layer. This rock mainly consists of potassic feldspar, nepheline, sodalite and aegirine, and contains accessory EGM, lamprophyllite, lomonosovite, loparite and interstitial villiaumite.

Sample 2 originates from the Kvanefjeld area, Ilímaussaq alkaline complex. It comprises brownish yellow grains and imperfect equant crystals up to 2 mm across in an agpaitic rock composed of potassic feldspar, albite, nepheline, aegirine and arfvedsonite.

Electron microprobe analyses (three spot analyses for each sample) were carried out using a Tescan VEGA-II XMU electronic microscope (EDS mode, 20 kV, 400 pA, Oxford Instruments plc, London, UK) housed at the Institute of Experimental Mineralogy RAS. Data reduction was carried out by means of a modified INCA Energy 450 software package (Oxford Instruments, Oxfordshire, UK). The size of the electron beam was 157–180 nm. The beam was rastered on an area 20 μm × 20 μm in order to minimize sample damage. The time of data acquisition was 50 s. The sample-to-detector distance was 25 mm. The standards used were: albite for Na and Si, sanidine for K, wollastonite for Ca, BaSO₄ for S, SrF₂ for Sr, individual REE(PO₄) for rare-earth elements, metallic Fe, Mn, Ti, Zr, Hf and Nb for corresponding elements, and NaCl for Cl. The contents of other elements with atomic numbers >8 were below detection limits. H₂O was not determined directly because of the paucity of material.

In order to obtain infrared (IR) absorption spectra, powdered samples were mixed with dried KBr, pelletized and analyzed using an ALPHA FTIR spectrometer (Bruker Optics, Karlsruhe, Germany) in the range 360–4000 cm⁻¹ with a resolution of 4 cm⁻¹ and 16 scans. An IR spectrum of an analogous pellet prepared from pure KBr was used as a reference.

3. Results

3.1. Chemical Composition of Samples 1 and 2

The chemical data of Samples 1 and 2 are presented in

Table 2. Chemical composition of the studied Fe-deficient EGMs (in wt.%).

Constituent	Sample 1		Sample 2
	Mean	Ranges	Mean	Ranges
Na2O	13.81	13.42–14.17	11.13	10.38–11.71
K2O	0.27	bdl–0.53	bdl	bdl
CaO	7.13	6.80–7.56	8.13	7.77–8.60
MnO	2.83	2.43–3.15	0.83	0.59–0.96
FeO	2.10	1.27–2.71	3.38	3.04–3.75
SrO	1.12	1.67–2.31	bdl	bdl
Y2O3	bdl	bdl	1.08	0.72–1.27
La2O3	0.91	0.68–1.15	1.85	1.63–2.05
Ce2O3	1.06	0.86–1.39	2.12	1.88–2.40
Nd2O3	0.34	0.21–0.48	0.50	0.41–0.66
SiO2	49.97	49.05–50.89	53.60	52.59–54.82
TiO2	0.87	0.69–1.04	0.92	0.76–1.18
ZrO2	15.24	14.88–15.57	11.13	10.84–11.43
HfO2	0.18	bdl–0.30	0.23	bdl–0.39
Nb2O5	0.91	0.79–1.11	1.05	0.85–1.26
SO3	0.38	bdl–0.63	0.23	bdl–0.37
Cl	0.93	0.70–1.27	0.43	0.36–0.48
–O=Cl	−0.21		−0.10
Total	97.84		96.51

Note: bdl = below detection limit; EGM = eudialyte-group minerals.

. The empirical formulae calculated on 25.48 and 25.80 Si atoms per formula unit, respectively (in accordance with structural data, Z = 3, see below) are as follows.

Sample 1:

(H₂O,H₃O)_xNa_13.65K_0.18Ca_3.90Mn_1.22Fe_0.90Sr_0.33La_0.17Ce_0.20Nd_0.06Ti_0.33Zr_3.79Hf_0.03Nb_0.22Si_25.48S_0.15Cl_0.80(O,OH)_y.

Sample 2:

(H₂O,H₃O)_xNa_10.39Ca_4.19Mn_0.34Fe_1.36Y_0.28La_0.33Ce_0.37Nd_0.09Ti_0.33Zr_2.61Hf_0.03Nb_0.23Si_25.80S_0.08Cl_0.35(O,OH)_y.

3.2. Infrared Spectroscopy of Samples 1 and 2

The IR spectra of Samples 1 and 2 (Figure 2) contain bands of O–H stretching vibrations (in the range 3200–3700 cm⁻¹), H–O–H bending vibrations (at 1650 and 1635 cm⁻¹), stretching vibrations of the rings of tetrahedra (in the range 1000–1100 cm⁻¹) and SiO₄ tetrahedra at the M3 and M4 sites (at the centers of 9-membered rings of tetrahedra) at 933 and 936 cm⁻¹. Broad absorption in the range 2600–3300 cm⁻¹ indicates the presence of H₃O⁺ groups. Bands in the range 650–750 cm⁻¹ correspond to mixed vibrations of the rings of tetrahedra (“ring bands”). Weak absorptions in the region 510–530 cm⁻¹ are related to Zr–O and Fe–O stretching modes of the M2-centered polyhedra. Bands below 500 cm⁻¹ are due to lattice mode involving predominantly bending vibrations of rings of tetrahedra, and stretching vibrations of M1-centered octahedra. Bands of CO₃²⁻ are absent in both spectra. The assignment of IR bands was made based on analyses of the IR spectra of several dozen structurally investigated eudialyte-group minerals, in accordance with [2].

The number of observed absorption maxima and shoulders in the IR spectrum of Sample 2 is less than in the IR spectrum of Sample 1. This is due to a high content of H₂O molecules and H₃O⁺ groups in Sample 2. The disordering of Na⁺, H₂O and H₃O⁺, as well as hydrogen bonding, result in the broadening of individual bands, their poor resolution and changes of peak intensities which are most significant for narrow bands.

3.3. Crystal Chemistry of Samples 1 and 2

The crystal structures of Samples 1 and 2 are published elsewhere [24,31]. In this subsection, we discuss only the crystal-chemical features in the microregions around the key sites M2–M4 (see

Table 3. Selected interatomic M–O distances (Å) in the structures of the Samples 1 and 2.

Sample 1				Sample 2
Site	Coord. Number	Ranges	Average	Site	Coord. Number	Ranges	Average
M1	6	2.295(8)–2.420(5)	2.350	M1	6	2.305(6)–2.394(3)	2.338
M2a	7	2.328(9)–3.045(8)	2.754	M2a	5	2.14(4)–2.34(1)	2.24
M2b	5	2.138(5)–2.31(7)	2.204	M2b	4	2.184(3)–2.184(3)	2.184
M3a	6	1.614(9)–1.94(2)	1.777	M3a	6	1.66(1)–1.99(4)	1.83
M3b	4	1.28(3)–1.53(1)	1.47	M3c	4	1.565(9)–1.67(3)	1.59
M3c	4	1.602(7)–1.63(1)	1.609
M4a	4	1.535(2)–1.62(3)	1.556
M4b	4	1.611(4)–1.82(4)	1.66
M4c	6	1.79(8)–1.903(7)	1.847

).

Sample 1 is trigonal, space group R3m; the unit cell parameters are a = 14.198(1) Å, c = 30.380(1) Å, and V = 5303.9(1) ų. The crystal structure was refined to a final reliability factor value R = 4.2% in the anisotropic approximation of atomic displacements using 3174 reflections with F > 3σ(F) [22]. All features of the distribution of cations between different sites in the structure of Sample 1 are reflected in its crystal chemical formula (Z = 3):

^ZZr₃^M1[Ca_3.9Mn_1.2Fe_0.9] ^N1–5[Na_11.4(H₃O,H₂O)_1.8Ce_0.45Sr_0.4K_0.2] ^M2[Na^VII_2.13Zr^V_0.87)] [Si₂₄O₇₂] ^M3–4[Si_1.48Ti_0.31Nb_0.21] ^X[(OH)_2.9 (H₂O)_1.26(Cl,S)_0.94], where the compositions of key sites are given in square brackets, and roman numerals denote coordination numbers. The simplified formula is (Na,H₃O)₁₃(Ca₄Mn₂)Zr₃(Na₂Zr)[Si₂₆O₇₂](OH)₂Cl·H₂O.

An excess of Zr (0.87 atoms per formula unit) was located at the M2a site in the square base pyramid with apical OH group and average Zr–O distance of 2.204 Å. This vertex also belongs to the NbO₆ octahedron located on the threefold axis, which results in the formation of a cluster [NbZr₃O₃] whose occupancy factor is equal to 0.21.

A large, elongated, Na-centered, seven-fold M2b polyhedron is characterized by the average Na–O distance of 2.754 Å. One base of this prism-like polyhedron is square, and another is a triangle involving two O atoms in the framework and one Cl atom located on the threefold axis. These two M2 polyhedra are turned in opposite directions and are only partially occupied, since the distance between the cations centering them is short, amounting to 1.781 Å.

The key sites M3 and M4 on the threefold axis are statistically occupied by Si-centered tetrahedra of two orientations with a common triangular base, and subordinate Ti and Nb atoms in octahedral coordination.

Large extra-framework cations are located at the sites N1–N4, which are split and mainly occupied by sodium atoms coordinated by 7- and 8-fold polyhedra with average distances within the range of 2.56–2.64 Å. Based on the number of refined electrons, one may suppose that the group of closely spaced N5 sites is occupied by hydronium groups and water molecules.

Short distances (Å) between statistically occupied cationic sites in Sample 1 are: M2a−M2b = 1.781(7); M3a–M3b = 0.23(3); M3a–M3c = 1.37(1); M3b–M3c = 1.14(2); M4a–M4b = 0.87(1); M4b–M4c = 0.59(1); M4a–M4c = 1.46(1); N1a–N1b = 0.72(1); N2a–N2b = 0.50(1); N4a–N4b = 0.27(4); N4a–N4c = 0.71(1); N4b–N4c = 0.95(3).

Sample 2 is trigonal, space group R-3m; the unit cell parameters are a = 14.208(1) Å, c = 30.438(2) Å, and V = 5321(1) ų. The crystal structure is refined to the final R = 5.6% for 1095 reflections with F > 3σ(F) in the anisotropic approximation of atomic displacements [31]. The crystal chemical formula (Z = 3) is ^Z[Zr_2.57Ti_0.4Hf_0.03] ^M1[Ca_4.3Fe_0.5Mn_0.4Na_0.3Y_0.3Ce_0.2] ^M2[^VNa₂^IVFe] ^M3[Si_1.8Nb_0.2 (OH)_2.4] ^N1–5[Na₆(Na,H₃O,H₂O)_8.4Ce_0.6] [Si₂₄O₇₂] ^X[(H₂O)_2.0Cl_0.4]. The simplified formula is (Na,H₃O)₁₅Ca₆Zr₃[Na₂Fe][Si₂₆O₇₂](OH)₂Cl·2H₂O.

The centrum of the M2 square is populated by Fe with an occupancy factor of 0.33 and Fe–O distances of 2.184 Å. Na atoms occupy two sites on both sides of the M2 square and are coordinated by additional OH groups with an average Na–O distance in the square pyramids of 2.236 Å. Since both Na subsites are located at short distances from the center of the square (0.59 Å) and from each other (1.18 Å), only one of them can be occupied in this microregion. The total occupancy factor of the three M2 subsites is equal to 1, which corresponds to two Na atoms and one Fe atom per formula unit (Z = 3).

The M3 microregion situated at the threefold axis contains two sites, one of which (with an occupancy factor of 0.8 and an average Si–O distance of 1.59 Å) contains Si in tetrahedral coordination, and another which contains Si with minor admixture of octahedrally coordinated Nb with an average Nb–O distance in the NbO₆ octahedron of 1.83 Å.

The N1b and N2a sites, located at the short distance of 0.48(1) Å from each other, are occupied by H₃O⁺ and H₃O⁺ with an admixture of Ln, respectively. Both sites have 8-fold coordination with the cation-oxygen distances in the ranges 2.56–2.69 and 2.48–3.04 Å, respectively.

The N4-site is split into two subsites (N4a and N4b) having 10-fold coordination and partially occupied by Na (with the occupancy factors of 0.6 and 0.4, respectively). The distances N4a–O, N4b–O and N4a–N4b are 2.46–2.99, 2.38–3.08 and 0.52 Å, respectively. Based on the number of refined electrons, and by analogy with other hydrated EGMs, one can suppose that The N5 hole is occupied by H₃O⁺ cations, H₂O molecules and OH groups belonging to the SiO₃(OH) tetrahedron attached to the center of the Si₉O₂₇ ring.

Other short distances (in Å) between statistically occupied cationic sites in Sample 2 are M2a–M2b = 0.590(1), M3b–M3c = 1.19(2), N1a–N1b = 0.48(1), N3a–N3b = 0.52(1) and N5–N5 = 2.00(4).

4. Discussion

About 150 years have passed since the description of eudialyte by Stromeyer in 1819 [1], but the structure of this mineral remained unknown for a long time, since it has a volume of more than 5000 ų. Another cause of this situation was unique crystal-chemical complexity and variability of eudialyte and related minerals (Table 1 and

Table 4. EGMs containing Na at the M2 site.

Sample No.	Lattice Parameters (a, c in Å); Space Group	Na-Polyhedra (Z = 3)	References
Eudialyte Structure Type
1.	14.198(1), 30.380(1); R3m	NaVII2.1	[24]
2.	14.208(1), 30.438(2); R-3m	NaV2.01	[31]
3.	14.226(4), 30.339(7); R-3m	NaVII2.2	[32]
4.	14.199(1), 30.305(1); R3m	NaVI0.7 + NaV0.6	[29]
5.	14.155(1), 30.998(1); R3m	NaIV2.3	[33]
6.	14.081(1), 30.525(3); R3m	NaIV0.62	[33]
7.	14.170(4), 30.38(2); R3m	NaIV2.4	[34]
8.	14.165(1), 30.600(5); R3m	NaVI2.2	[35]
9.	14.220(1), 30.539(1); R3m	NaV1.9	[2]
Raslakite Structure Type
10.	14.208(1), 30.384(1); R3	NaIV2.4	[30]
11.	14.1944(4), 30.294(1); R3	NaVII1.75	[27]
12.	14.229(7), 30.019(5); R3	NaV1.5	[36,37]
13.	14.218(1), 30.349(2); R3	NaIV1.8 + NaVI0.6	[30,38]
14.	14.078(3), 31.24(1); R3	NaIV2.2	[39,40]
15.	14.182(7), 30.37(1); R3	NaV1.8	[41]
16.	14.222(3), 30.165(5); R3	NaV0.9 + NaV0.45	[42,43]
Alluaivite Structure Type
17.	14.046(2), 60.60(2); R-3m	NaIV3/NaVII2.34	[44]
18.	14.069(4), 60.63(1); R-3m	NaIV3/NaIV1.59	[21]
19.	14.153(9), 60.72(5); R3m	NaV1.5/NaV1.5	[45,46]
20.	14.239(1), 60.733(7); R3	NaIV1NaVII2/FeIV2.2	[47,48]
21.	14.249(1), 60.969(1); R3m	NaIV1KVII2/FeIV3	[49,50]
22.	14.179(1), 60.67(1); R-3m	NaIV2.4/MnV2.46	[51]
23.	14.2032(1), 60.6118(7); R-3m	NaIV3/FeIV 1.25	[10]

Note: Roman numerals denote coordination numbers. A part of the data corresponds to holotype samples of EGMs: raslakite (12), sergevanite (13), aqualite (14), alluaivite (17), dualite (19), labirinthite (20) and rastsvetaevite (21).

).

Only in the early 1970s was the structural motive of eudialyte characterized in general terms by a group of researchers led by academician N.V. Belov [52,53], and almost simultaneously by G. Giuseppetti et al. [54]. Further studies of the structure of eudialyte revealed its complexity and variety of structural fragments.

Mineral species belonging to the eudialyte group are distinguished by symmetry (representatives with the space groups R3m, R-3m and R3 are known) and different combinations of predominant components at the key sites [2,3,4,5,6,7]. In addition, there is a subgroup of EGMs with modular structures and doubled c parameter of the unit cell. The distribution of cations among key sites is the result of a combination of two factors: the competition of their activities in the mineral-forming medium, and their affinity to different sites in the structures of EGMs.

The structural complexity of EGMs results from an unusual diversity of their fragments, including a three-membered ring of tetrahedra (Si₃O₉), two nonequivalent, nine-membered rings of tetrahedra (Si₉O₂₇) and a six-membered ring of edge-sharing octahedra M1₆O₂₄ (M1 = Ca, Mn²⁺, Fe²⁺, Na, Ln, Sr: Figure 3) combined into a heteropolyhedral framework via isolated ZO₆ octahedra. Additional key sites M3 and M4 are located at the centers of the Si₉O₂₇ rings, and can be vacant or occupied by different components, including ^[4]Si, ^[4]Al, ^[6]Nb, ^[6]W, Na. Large cations (Na⁺, K⁺, H₃O⁺, Ca²⁺, Sr²⁺, REE³⁺, etc.) occupy extra-framework sites N1–N5, which are typically split. Additional anions (Cl^–, F^–, OH^–, S^2–, SO₄^2–, CO₃^2–) and water molecules occur at two sites on the threefold axis.

The crystallochemical diversity of EGMs is determined by complex mechanisms of isomorphism accompanied by the splitting of positions and variations in their coordination numbers [2]. The most complex isomorphism schemes are realized at the group of the M2 sites in the microregion between two neighboring M1₆O₂₄ octahedra. Eudialyte s.s. is a Na- and Si-rich EGM in which the M2 site is occupied by Fe²⁺ with flat-square coordination. However, different Fe-deficient members of the eudialyte group are known. In these minerals, the deficiency of iron at the M2 site is compensated for by other cations (Fe²⁺, Fe³⁺, Ti⁴⁺, Hf⁴⁺, Zr⁴⁺, Ta⁵⁺, Mn²⁺, and Mg²⁺). The agpaitic and, especially, hyperagpaitic rocks of some alkaline massifs are characterized by the prevalence of ^M2Na-dominant minerals over other EGMs.

The substitution of Fe²⁺ by Na⁺ (usually accompanied by the change of the coordination number from 4 to 5, 6 or 7) is a specific crystal-chemical feature of these EGMs. Additional O atoms coordinating ^M2Na belong to H₂O molecules or to OH groups of the M3(O,OH)₆ and M4(O,OH)₆ octahedra or SiO₃(OH) tetrahedra occurring on the threefold axes at the centers of the Si₉O₂₇ rings. The 5-, 6- and 7-fold Na-centered M2 polyhedra are based on the square formed by four O atoms of the neighboring M1₆O₂₄ rings (Figure 4 and Figure 5).

Table 4 contains data on the distribution of Na atoms at the M2-key site in the structurally studied ^M2Na-dominant EGMs, most of which were found in the Lovozero massif. The exceptions are Sample 2 (Table 4), from Ilímaussaq, Greenland, labyrinthite and rastsvetaevite (Samples 20 and 21 in Table 4, respectively) which originate from the Khibiny massif and two hydrated samples from the Inagli massif, Eastern Siberia (Samples 5 and 6 in Table 4). It is to be noted that Lovozero is characterized by manganese specificity and differs from the Khibiny massif in its significantly lower iron content.

The M2 site can be split into two or more subsites. Usually, the M2O₄ square (Figure 5a and Figure 6) is filled with Fe²⁺; less often, it contains Na. Zr, Hf and Ta may also be present as subordinate and impurity components in this position. The four-fold coordination of ^M2Na is a specific feature of alluaivite [44].

The M2 semioctahedron or square pyramid is a pentahedron formed on the basis of a square with the addition of an OH-group belonging to the M3 or M4 octahedron (Figure 5b and Figure 7). This polyhedron can be occupied by Na⁺, Fe²⁺, Fe³⁺, or Mn²⁺.

The M2 octahedron is formed when the square coordination is supplemented by the two OH groups of the axial M3 and M4 octahedra, or by water molecules (Figure 5c and Figure 8). Besides Na⁺, the cations Fe²⁺, Fe³⁺ and Mn²⁺ may enter the M2 octahedron.

The largest seven-fold M2 polyhedra are built on the basis of the square involving O atoms of the framework (Figure 9), additional anions and/or water molecules occurring on the threefold axis. Such coordination is known for ^M2Na⁺, ^M2Mn²⁺ and ^M2Zr⁴⁺. ^M2NaO₇ polyhedra are dominant in the structures described in [32,34]. As subordinate components, such polyhedra (with the Na–O distances in the ranges of 2.23(4)–2.96(3) and 2.33(1)–3.01(1) Å) occur in the structures of intermediate members of the manganoeudialyte-ilyukhinite [25] and eudialyte-sergevanite [27] series, respectively.

The diagnostic signs of ^M2Na-EGMs are the specific features of their chemical composition (low total content of Fe + Mn + Ca, i.e., usually less than 7 atoms per formula unit, Z = 3, at relatively high Si contents) and reduced intensities of the IR bands in the range 515–545 cm^–1, corresponding to ^M2Fe–O and ^M2Mn–O stretching vibrations. Until recently, these minerals were known exclusively in hyperagpaitic igneous rocks and pegmatites of the Lovozero alkaline massif, which are indicated by highly alkaline titano-, zircono- and niobo- silicates (with atomic ratios Na:Si ≥ 1) such as lomonosovite, vuonnemite, zirsinalite, kazakovite, etc. [55]. Unlike the neighboring Khibiny alkaline massif, where even high-sodium EGMs typically do not contain ^M2Na and mainly occur in pegmatites, in the Lovozero complex, these minerals are common components of specific igneous rocks (hyperagpaitic varieties of foyaite), and are often ^M2Na-dominant.

^M2Na-EGMs belong to three structure types: eudialyte (with disordered population of the M1 octahedra, space groups R3m or R-3m), raslakite (with ordering of Ca and smaller cations, Fe²⁺ in raslakite and Mn²⁺ in sergevanite; space group R3) and alluaivite (EGMs with doubled c parameter including alluaivite, dualite, rastsvetaevite and labyrinthite). ^M2Na-EGMs 1, 3 and 7 in Table 4 belong to the eudialyte structure type and are Fe-deficient, with a strong predominance of Na over Fe at M2. Consequently, these samples can be considered as representatives of a potentially new mineral species.

In the structure of the Mn-rich alluaivite-type Sample 22 (Table 4), ^M2Na-dominant modules alternate with kentbrooksite (Figure 10). In rastsvetaevite (Figure 11), labyrinthite and a centrosymmetric analogue of labyrinthite (Samples 21, 20 and 23 in Table 4, respectively) ^M2Na-dominant modules alternate with eudialyte. The alternation of modules with different populations at the M2 site is one of the main causes of the unit-cell doubling in these minerals.